WORKOVER RIG WITH REINFORCED MAST
A reinforced workover rig mast (40) is disclosed. A top section (60) of the mast (40) telescopes relative to a mid section (44), and includes a scoping cylinder area (72) for receiving a scoping cylinder (90) that may be used to extend and retract the top section (60). A number of external gussets (78) are located within this scoping cylinder area (72) to structurally reinforce the upper section (60). Other reinforcement features are incorporated by the mast (40) as well, including an increased width and depth, along with a reduced vertical spacing between adjacent cross supports (50b, 66b, 74).
This patent application is a continuation of U.S. patent application Ser. No. 11/772,851, that is entitled “WORKOVER RIG WITH REINFORCED MAST,” and that was filed on Jul. 3, 2007, which claims priority under 35 U.S.C. §119(e) to U.S. Provisional Patent Application Ser. No. 60/895,026, that is entitled “WORKOVER RIG WITH REINFORCED MAST,” and that was filed on Mar. 15, 2007. Priority is claimed to each of the above-noted patent applications, and the entire disclosure of each of the above-noted patent applications is hereby incorporated by reference in their entirety herein.
FIELD OF THE INVENTIONThe present invention generally relates to the field of service or workover rigs and, more particularly, to the derrick or mast used by such rigs.
BACKGROUND OF THE INVENTIONTwo general categories of rigs include drilling rigs and service/workover rigs. Drilling rigs are used to drill wells (e.g., oil, natural gas), while service/workover rigs are used to service or work existing wells for any appropriate reason. Representative servicing or workovers of existing wells includes without limitation replacing one or more components (including downhole components) associated with the well (e.g., tubing, valves, seals, flanges, blowout preventers), directing one or more components into the well for any appropriate purpose (e.g., a tool for opening a downhole blockage), executing one or more well operations (e.g., fracturing, acidizing), or the like.
Both drilling and service/workover rigs typically use a derrick or mast that supports one or more pulleys, one or more block and tackles, or the like. Various lines, cable, or the like may be directed around one or more of these pulleys/block and tackles to lift the desired component(s) and/or to lower the desired component(s) as desired/required. These lines or cables are anchored to what is commonly referred to in the art as a drawworks. An appropriate power source (e.g., a right angle drive) rotates one or more drums of the drawworks in one direction to wind the line/cable around one or more drums of the drawworks to lift the desired component(s), while the power source rotates one or more drums of the drawworks in the opposite direction to unwind the line/cable from one or more drums of the drawworks to lower the desired component(s). “Cable” is commonly viewed as being of a heavier grade than “line,” and thereby more appropriate for handling heavier components. Cable is commonly associated with a main drum of a drawworks, while line is commonly associated with a sand drum of a drawworks. Service or workover rigs use a drawworks having both a main drum and a sand drum, while drilling rigs typically only use a main drum.
The mast or derrick of service/workover rigs oftentimes extends in excess of 90 feet. Many service/workover rigs are incorporated by a truck/tractor for transporting the same from location to location. Moreover, the mast is typically movable between a stowed position (e.g., at least generally horizontal, and including for transportation purposes) and a deployed position (e.g., at least generally vertical, although in practice most masts are disposed at a small angle relative to vertical). In addition to being deployable, the mast should be designed to accommodate the loads that will be experienced during operation of the service/workover rig.
SUMMARY OF THE INVENTIONA first aspect of the present invention is generally directed to a service or workover rig mast that includes at least a first mast section. The first mast section includes a frame, what may be characterized as a pocket or a scoping cylinder area within the frame, and a plurality of gussets. The scoping cylinder area may be in the form of a space for accommodating a component or combination of components that may be used to deploy the first mast section (e.g., a scoping cylinder), such as to pivot the first mast section and/or extend the first mast section to move the first mast section between a stowed position and a deployed position. In any case, each gusset is both disposed within the scoping cylinder area and is appropriately anchored to the frame.
Various refinements exist of the features noted in relation to the first aspect of the present invention. Further features may also be incorporated in the first aspect of the present invention as well. These refinements and additional features may exist individually or in any combination. The workover rig mast may be incorporated by a service or workover rig of any appropriate size, shape, configuration, and/or type. In one embodiment, the first mast section defines an uppermost portion of the workover rig mast. The first mast section may also be characterized as incorporating what is commonly referred to in the art as the “crown” of a workover rig.
The workover rig mast may also incorporate a second mast section in a manner such that the first mast section telescopes relative to the second mast section and extends to a higher elevation than the second mast section when the workover rig mast is moved from a stowed position (e.g., where the workover rig mast is at least generally horizontally disposed or oriented) to a deployed position (e.g., where the workover rig mast is at least generally vertically disposed or oriented, and including where the workover rig mast is disposed within a small angle of absolute vertical). This second mast section may be in the form of a three-sided structure in a view corresponding with a cross-section taken perpendicularly to the length of the second mast section. In one embodiment, the width of the second mast section is measured between opposing closed sides of the second mast section, while the depth of the second mast section is measured between an open end of the second mast section and an opposing closed end of the second mast section.
In one embodiment and in relation to the above-noted general configuration for the second mast section: 1) its width is at least about 8 feet; 2) its depth is at least about 4 feet; 3) it may incorporate a plurality of what may be characterized as second cross support assemblies (e.g., “internal” C-girts) that are spaced along the length of the second mast section by a distance of no more than about 5 feet (e.g., where each second cross support assembly includes three commonly oriented cross supports). These dimensional features may be utilized individually and in all combinations in relation to the workover rig mast. Moreover, one embodiment has each of the noted second cross support assemblies being disposed within a corresponding plane that is orthogonal to the length of the second mast section (e.g., the various second cross support assemblies may be characterized as being disposed within a plurality of spaced, parallel planes). Further in this regard, the second mast section may further include a plurality of diagonal supports, where each such diagonal support at least generally extends between a corresponding adjacent pair of second cross support assemblies (i.e., each diagonal support of the second mast section is not required to extend between the same two second cross support assemblies). Each such diagonal support may be appropriately attached to a corresponding second cross support assembly and/or a corresponding corner support or derrick leg.
The first mast section may incorporate a plurality of what may be characterized as first cross support assemblies (e.g., “internal” C-girts) that are spaced along the length of the first mast section by a distance of no more than about 5 feet (e.g., where each first cross support assembly includes three commonly oriented first cross supports). A first mast section of this particular type may be utilized for any of the configurations noted herein, including in combination with a second mast section having the above-noted 5 foot maximum spacing between adjacent second cross support assemblies. Moreover, one embodiment has each of the noted first cross support assemblies being disposed within a corresponding plane that is orthogonal to the length of the first mast section (e.g., the various first cross support assemblies may be characterized as being disposed within a plurality of spaced, parallel planes). Further in this regard, the first mast section may further include a plurality of diagonal supports, where each such diagonal support at least generally extends between a corresponding adjacent pair of first cross support assemblies (i.e., each diagonal support of the first mast section is not required to extend between the same two first cross support assemblies). Each such diagonal support may be appropriately attached to a corresponding first cross support assembly and/or a corresponding corner support or derrick leg.
The above-noted general configuration for the second mast section may be characterized as including a plurality of second perimeter supports that collectively define the above-noted three-sided structure. Each of these second perimeter supports may be further characterized as being disposed within a plane that is orthogonal to the length of the second mast section, where a spacing of no more than about 5 feet exists between each adjacent pair of second perimeter supports that are aligned and spaced in a dimension corresponding with the length of the second mast section.
The above-noted general configuration for the second mast section may also be characterized as including a plurality of second cross supports that are each disposed in a common orientation. Such a “common orientation” may be where each such second cross support is co-planar with one or more other second cross supports, is parallel with one or more other second cross supports, or both. In any case and in one embodiment, each adjacent pair of second cross supports that are both aligned and spaced in a dimension corresponding with the length of the second mast section are separated by distance of no more than about 5 feet.
The first mast section may include a plurality of first cross supports that are each disposed in a common orientation. Such a “common orientation” may be where each such first cross support is co-planar with one or more other first cross supports, is parallel with one or more other first cross supports, or both. In any case and in one embodiment, each adjacent pair of first cross supports that are both aligned and spaced in a dimension corresponding with the length of the first mast section are separated by distance of no more than about 5 feet. A first mast section of this particular type may be utilized for any of the configurations noted herein, including in combination with a second mast section having the above-noted 5 foot maximum spacing between adjacent second cross supports that are aligned and spaced from each other in a dimension corresponding with the length of the second mast section. In one embodiment, the various first cross supports and the various second cross supports are disposed in the same orientation.
The above-noted general configuration for the second mast section may also be characterized as including first, second, third, and fourth corner supports or derrick legs, where each such corner support extends in or defines a length dimension of the second mast section. Consider the case where a reference plane extends between the outer perimeter of each of the four adjacent pairs of the corner supports. In this case, the second mast section may further include a plurality of cross supports, where each such cross support extends between and is anchored to only a corresponding pair of the first, second, third, and fourth corner supports, and where each such cross support fails to protrude beyond the corresponding reference plane (e.g., to define an “internal” C-girt). This particular “corresponding pair” may be any two of the first, second, third, and fourth corner supports. That is, each cross support need not extend between and be anchored to the same two corner supports. For instance, one cross support could extend between and be anchored to the first and second corner supports, while another cross support could extend between and be anchored to the third and fourth corner supports. Another related characterization is that second mast section may lack any “external” C-girts, where an external C-girt would be an at least generally C-shaped structure that would be disposed on the outside of the noted first, second, third, and fourth corner supports to define one open side or end for the second mast section.
The workover rig mast may be of a light-weight construction. One characterization in this regard is that the workover rig mast has a weight of no more than about 22,000 pounds and a length of at least about 95 feet in one embodiment. Another characterization in this regard is that the workover rig mast weighs no more than about 210 pounds per linear foot in the length dimension in another embodiment. Yet another characterization in this regard is that a frame of the first mast section is defined by ASTM 500 Grade C steel in yet another embodiment.
A number of characterizations may be made in relation to the gussets utilized by the first mast section of the workover rig mast, and which are applicable to each of the various configurations presented herein. Each gusset may be characterized as being located in a corresponding corner of the frame within the scoping cylinder area. In the case where the length of the first mast section extends in or defines a first dimension, a plurality of gusset groups may be spaced along the first dimension or length of the first mast section, and where each gusset group includes at least one and more typically a plurality of gussets. In one embodiment, a length dimension of each gusset in a common gusset group is disposed within a common plane that is orthogonal to the first dimension, which again corresponds with or defines the length of the first mast section.
Each gusset may also be characterized as having first and second ends. In one embodiment, the first and second ends of the gussets in a common gusset group are disposed in a common plane that is orthogonal to the length dimension of the first mast section. In another embodiment, the first and second ends of a first plurality of gussets are disposed in a common first plane that is orthogonal to the length dimension of the first mast section, while the first and second ends of a second plurality of gussets are disposed in a common second plane that is also orthogonal to the length dimension of the first mast section.
The frame of the first mast section may be characterized as including first, second, third, and fourth corner supports or derrick legs that each extend in or define a length dimension of the first mast section. One end of each of the various gussets may be fixed to either the first or the second corner support (e.g., not all gussets need to be fixed to the same corner support; one or more gussets may be fixed to the first corner support, and one or more gussets may be fixed to the second corner support). An opposite end of each of the various gussets may be fixed to a corresponding one of a plurality of internally disposed cross members of the frame. Not all gussets need to be fixed to the same internally disposed cross member. For instance, one pair of gussets may be fixed to a first internal cross member, while another pair of gussets may be fixed to a second internal cross member that is spaced from the first internal cross member along the length dimension of the first mast section.
A second aspect of the present invention is generally directed to a service or workover rig mast that includes first and second mast sections. The first mast section telescopes relative to the second mast section, and extends to a higher elevation than the second mast section when the workover rig mast is in a deployed position versus a stowed position (e.g., the second mast section is closer to the ground when the workover rig mast is in its deployed position). Furthermore, the first mast section includes a frame, that in turn includes first, second, third, and fourth corner supports or derrick legs, along with a plurality of gussets. One end of each of the gussets is fixed to either the first corner support or the second corner support (e.g., one or more of the gussets may be fixed to the first corner support, while one or more of the gussets may be fixed to the second corner support), while the opposite end of each of gusset is fixed to a corresponding one of a plurality of internally disposed cross members of the frame (e.g., one or more of the gussets may be fixed to a first internal cross member, while one or more of the gussets may be fixed to a second internal cross member that is spaced from the first internal cross member along the length of the first mast section). The various features discussed above in relation to the first aspect may be used by this second aspect, alone or in any combination.
The workover rig 10 further includes a drawworks 30 having both a main drum 38 and a sand drum 34. A cable 20 is typically associated with the main drum 38, while a wire line 22 is typically associated with the sand drum 34 (e.g., the cable 20 generally being more robust or stronger than the wire line 22, and thereby accommodating a higher or heavier load). Each of the cable 20 and wire line 22 may be of any appropriate size, shape, configuration, and/or type (each being of an at least generally elongated configuration and sufficiently flexible so as to be able to wrap around the associated main drum 38 or sand drum 34). The cable 20 is anchored to the main drum 38 and extends through a crown schieve 24a on the derrick 18 (and typically through one or more other schieves on the derrick 18—not shown), while the wire line 22 is anchored to the sand drum 34 and extends through another crown schieve 24b on the derrick 18. The crown schieves 24a, 24b are only schematically illustrated in
A component 28a is schematically illustrated in
The drawworks 30 is used to raise and lower the component 28a via the cable 20 and rotation of the main drum 38, while the drawworks 30 is used to raise and lower the component 28b via the wire line 22 and rotation of the sand drum 34. In this regard and for the illustrated embodiment, an engine/transmission 14 (only schematically illustrated) of the carrier 12 is also used to operate a right angle drive 16 (only schematically illustrated), which in turn is used to power the drawworks 30 (e.g., to rotate the sand drum 34, and which may also then rotate the main drum 38).
One embodiment of a reinforced service or workover rig mast or derrick is illustrated in
One portion of the scoping cylinder 90 is associated with the midsection 44 or sub-base 42, while another portion of the scoping cylinder 90 is appropriately attached to or interconnected with the top section 60 of the workover rig mast 40 in any appropriate manner. Extension of the scoping cylinder 90 at least axially advances the top section 60 away from the mid section 44 to dispose the workover rig mast 40 in the deployed position of
The above-noted extension of the scoping cylinder 90 also may be used to move the workover rig mast 40 from an at least generally prone or horizontal position to an at least generally vertical position as previously noted, although this function could be provided by another drive source as well and as noted. Typically the workover rig mast 40 will be disposed at a slight angle relative to absolute vertical in the deployed position, although such may not be required in all instances (e.g., the workover rig mast 40 may be disposed in a vertical orientation or within a small angular range of vertical). Retraction of the scoping cylinder 90 (whether actively driven, whether relying upon gravitational forces, or both) may be used to retract the top section 60 of the workover rig mast 40 relative to the mid section 44, to move the workover rig mast 40 from the deployed position of
The mid section 44 of the workover rig mast 40 includes four corner supports or mid section derrick legs 46 that extend in or define the length dimension of the mid section 44. The mid section 44 also includes a plurality of what may be characterized as cross support assemblies or “internal” C-girts 48 (in contrast to the external C-girts 48′ used by the prior art mast 40′, and that is addressed below) that are spaced along the length dimension of the mid section 44 and that are each appropriately attached to each derrick leg 46 (e.g., welded). Each internal C-girt 48 includes a cross support 50b that may be characterized as defining a closed end for the mid section 44 and that is appropriately attached to a corresponding pair of mid section derrick legs 46 (e.g., welded), along with a pair of cross supports 50a that may be characterized as being located at or defining opposing sides of the mid section 44 and that are each appropriately attached to a corresponding pair of mid section derrick legs 46 (e.g., welded). That is, each internal C-girt 48 is at least generally in the form of a C-shaped or U-shaped structure in the illustrated embodiment, having an open end 54. Each internal C-girt 48 may be characterized as being disposed within a plane that is orthogonal to the length dimension of the mid section 44. In any case, one or more diagonal supports 52 also extend at least generally between each adjacent pair of internal C-girts 48. Each end of each diagonal support 52 may be appropriately attached to a corresponding internal C-girt 48 and/or to a corresponding mid section derrick leg 46 (e.g., welded).
The top section 60 of the workover rig mast 40 may be characterized as including a frame 62. This frame 62 includes four corner supports or top section derrick legs 63 that extend in or define the length dimension of the top section 60. The top section 60 also includes a plurality of what may or be characterized as cross support assemblies or internal C-girts 64 (in contrast to the “external” C-girts 64′ used by the prior art mast 40′, and that is addressed below) that are spaced along the length dimension of the top section 60 and that are each appropriately attached to each top section derrick leg 63 (e.g., welded). Each internal C-girt 64 includes a cross support 66b that may be characterized as defining a closed end for the top section 60 and that is appropriately attached to a corresponding pair of top section derrick legs 63 (e.g., welded), along with a pair of cross supports 66a that may be characterized as being located at or defining the sides of the top section 60 and that are each appropriately attached to a corresponding pair of top section derrick legs 63 (e.g., welded). That is, each internal C-girt 64 is at least generally in the form of a C-shaped or U-shaped structure, having an open end 70. Each internal C-girt 64 may be characterized as being disposed within a plane that is orthogonal to the length dimension of the top section 60. In any case, one or more diagonal supports 68 also extend at least generally between each adjacent pair of internal C-girts 64. Each end of each diagonal support 68 may be appropriately attached to a corresponding internal C-girt 64 and/or to a corresponding top section derrick leg 63 (e.g., welded).
The top section 60 includes what may be characterized as a pocket or a scoping cylinder area 72 (
The workover rig mast 40 may be characterized as being structurally reinforced. There are a number of features that enhance this structural reinforcement.
Another reinforcement feature utilized by the mid section 44 of the workover rig mast 40 is the spacing between corresponding pairs of cross supports 50a (i.e., those that are in a common horizontal position or at a common elevation when the workover rig mast 40 is disposed in a vertical orientation, or those cross supports 50a of a common internal C-girt 48), or stated another way the width of the mid section 44 or the width of the open end 54. Each such corresponding pair of cross supports 50a of the mid section 44 is separated by a distance W1 of at least about 8 feet in one embodiment. That is, the width of the mid section 44 or the width of the open end 54 corresponds with the dimension W1, and is at least about 8 feet in one embodiment.
The spacing between adjacent cross supports 50b′ for the prior art workover rig mast 40′ is identified as H2, and which is at least about 7 feet in one known design (compared to a spacing of no more than about 5 feet for the embodiment noted above in relation to
Two desirable reinforcement features are also illustrated by
The spacing between adjacent cross supports 50a′ for the prior art workover rig mast 40′ is identified as H2, and which is at least about 7 feet in one known design (compared to no more than about 5 feet for the embodiment noted above in relation to
Two internal gussets 76 are provided for each internal C-girt 64. One end of each internal gusset 76 is appropriately attached to the corresponding top section cross support 74. Each internal gusset 76 extends from its corresponding top section cross support 74 at least generally in the direction of the open end 70 of the top section 60 where its opposing end is appropriately attached to a corresponding cross support 66a. Therefore, each internal gusset 76 faces or projects toward the open end 70 of the top section 60. In one embodiment, each internal gusset 76 has a length of at least about 26 inches.
Two gussets 78 are provided for each internal C-girt 64. One end of each external gusset 78 is appropriately attached to the corresponding top section cross support 74 (e.g., welded). Each external gusset 78 extends from its corresponding top section cross support 74 at least generally away from the open end 70 of the top section 60 where its opposing end is appropriately attached to a corresponding top section derrick leg 63 (e.g., welded). Therefore, each external gusset 78 is disposed within the scoping cylinder area 72. In one embodiment, each external gusset 78 is shorter than its corresponding internal gussets 76, and in another embodiment each external gusset 78 has a length of no more than about 20 inches. Generally, the various external gussets 78 structurally reinforce the top section 60, including reducing the potential for a twisting of the top section 60 about its length dimension. Twisting of the top section 60 can be attributed to the top section 60 incorporating a crown 80, and is the location where loads are principally applied to the mast 40 during operation of the workover rig.
A number of additional characterizations may be made in relation to each external gusset 78. The two external gussets 78 associated with each internal C-girt 64 may be characterized as being disposed within a common plane. That is, the pair of cross supports 66a and top section internal cross support 74 of a cross support assembly 64 may be characterized as being disposed within a common plane, along with its corresponding pair of external gussets 78. This plane may be orthogonal to the length dimension of the top section 60. Therefore, the top section 60 may be characterized as including a plurality of groups of external gussets 78 that are spaced along the length dimension of the top section 60, where each group includes a pair of external gussets 78 that are associated with a common internal C-girt 64 and furthermore that are disposed within a common plane.
Although the workover rig mast 40 may be formed from any appropriate material, in one embodiment the mid section 44 and at least the top section derrick legs 63 and internal C-girts 64 of the top section 60 are formed from ASTM 500 Grade steel. This same material may be utilized for the gussets 76, 78 as well. Using this type of material, along with the above-noted reinforcement features, provides a suitable strength for the workover rig mast 40 at a reduced weight. This reduced weight is subject to a number of characterizations. One is that the workover rig mast 40 has a length of at least about 95 feet and weighs no more than about 22,000 pounds in one embodiment. Another is that the workover rig mast 40 weighs no more than about 210 pounds per linear foot in its length dimension.
Two internal gussets 76′ are provided for each of the noted cross support assemblies. One end of each internal gusset 76′ is appropriately attached to the corresponding top section cross support 74′. Each internal gusset 76′ extends from its corresponding top section cross support 74′ at least generally in the direction of the open end 70′ of the top section 60′ where its opposing end is appropriately attached to a corresponding cross support 66a′. Therefore, each internal gusset 76′ faces or projects toward the open end 70′ of the top section 60′. In one embodiment, each internal gusset 76′ has a length of at least about 26 inches. Therefore, the top section 60′ lacks the reinforcement provided by the external gussets 78 of the top section 60 of
The foregoing description of the present invention has been presented for purposes of illustration and description. Furthermore, the description is not intended to limit the invention to the form disclosed herein. Consequently, variations and modifications commensurate with the above teachings, and skill and knowledge of the relevant art, are within the scope of the present invention. The embodiments described hereinabove are further intended to explain best modes known of practicing the invention and to enable others skilled in the art to utilize the invention in such, or other embodiments and with various modifications required by the particular application(s) or use(s) of the present invention. It is intended that the appended claims be construed to include alternative embodiments to the extent permitted by the prior art.
Claims
1. A workover rig mast, comprising:
- a first mast section comprising a frame, a pocket within said frame, and a plurality of gussets disposed within said pocket and attached to said frame.
2. The workover rig mast of claim 1, wherein said first mast section defines an uppermost portion of said workover rig mast.
3. The workover rig mast of claim 1, wherein said first mast section comprises a crown.
4. The workover rig mast of claim 1, further comprising a second mast section, wherein said first mast section telescopes relative to said second mast section and extends to a higher elevation than said second mast section when in a deployed position versus a stowed position, wherein said second mast section comprises a width, a depth, and a length, wherein said second mast section is a three-sided structure in a cross-section taken perpendicularly to its said length, wherein said width of said second mast section is measured between opposing closed sides of said second mast section, and wherein said depth of said second mast section is measured between an open end of said second mast section and an opposing closed end of said second mast section.
5. The workover rig mast of claim 4, wherein said width is at least about 8 feet.
6. The workover rig mast of claim 5, wherein said depth is at least about 4 feet.
7. The workover rig mast of claim 6, wherein said second mast section comprises a plurality of second cross support assemblies that are spaced along said length of said second mast section by a distance of no more than about 5 feet.
8. The workover rig mast of claim 4, wherein said depth is at least about 4 feet.
9. The workover rig mast of claim 4, wherein said second mast section comprises a plurality of second cross support assemblies that are spaced along said length of said second mast section by a distance of no more than about 5 feet.
10. The workover rig mast of claim 9, wherein each said second cross support assembly is at least generally disposed within a plane that is orthogonal to said length of said second mast section.
11. The workover rig mast of claim 10, wherein said second mast section further comprises a plurality of diagonal supports that at least generally extend between adjacent said pairs of said second cross support assemblies.
12. The workover rig mast of claim 9, wherein said first mast section comprises a plurality of first cross support assemblies that are spaced along a length of said first mast section by a distance of no more than about 5 feet.
13. The workover rig mast of claim 12, wherein each said first cross support assembly of said first mast section is at least generally disposed within a plane that is orthogonal to said length of said first mast section.
14. The workover rig mast of claim 13, wherein said first mast section further comprises a plurality of diagonal supports that at least generally extend between adjacent said pairs of said first cross support assemblies.
15. The workover rig mast of claim 4, wherein said second mast section comprises a plurality of second cross supports that define its said three-sided structure, wherein each said second cross support is at least generally disposed within a plane that is orthogonal to said length of said second mast section, and wherein a spacing of no more than about 5 feet exists between each adjacent pair of said second cross supports that are aligned in a dimension corresponding with said length of said second mast section.
16. The workover rig mast of claim 4, wherein said second mast section comprises a plurality of second cross supports that are each disposed in a common orientation, wherein each adjacent pair of said second cross supports that are aligned and spaced in a dimension corresponding with said length of said second mast section are separated by a distance of no more than about 5 feet.
17. The workover rig mast of claim 16, wherein said first mast section comprises a plurality of first cross supports that are each disposed in a common orientation, wherein each adjacent pair of said first cross supports that are aligned and spaced in a dimension corresponding with a length of said first mast section are separated by a distance of no more than about 5 feet.
18. The workover rig mast of claim 17, wherein said plurality of first cross supports and said plurality of second cross supports are each disposed in a common orientation.
19. The workover rig mast of claim 4, wherein said second mast section comprises first, second, third, and fourth corner supports that each extend in a length dimension of said workover rig mast, wherein a separate reference plane extends between an outer surface of each adjacent pair of said first, second, third, and fourth corner supports, wherein said second mast section further comprises a plurality of cross supports, wherein each said cross support extends between and is attached to only a corresponding pair of said first, second, third, and fourth corner supports and furthermore fails to protrude beyond its corresponding said reference plane.
20. The workover rig mast of claim 4, wherein said second mast section lacks any C-girts.
21. The workover rig mast of claim 1, wherein said first mast section comprises a plurality of first cross supports that are each disposed in a common orientation, wherein each adjacent pair of said first cross supports that are aligned and spaced in a dimension corresponding with a length of said first mast section are separated by a distance of no more than about 5 feet.
22. The workover rig mast of claim 1, wherein said workover rig mast has a length of at least about 95 feet and weighs no more than about 22,000 pounds.
23. The workover rig mast of claim 1, wherein said workover rig mast weighs no more than about 210 pounds per linear foot along its length dimension.
24. The workover rig mast of claim 1, wherein said frame comprises ASTM 500 Grade C steel.
25. The workover rig mast of claim 1, further comprising a scoping cylinder extending through said pocket and interconnected with said frame, wherein an extension of said scoping cylinder elevates said first mast section.
26. The workover rig mast of claim 1, wherein each said gusset is located in a corresponding corner of said frame within said deployment shaft pocket.
27. The workover rig mast of claim 1, wherein a length of said first mast section extends in a first dimension, wherein said plurality of gussets comprises a plurality of groups that are spaced along said first dimension, and wherein a length dimension of said gussets that are in a common said group are at least generally disposed within a common plane that is orthogonal to said first dimension.
28. The workover rig mast of claim 1, wherein a length of said first mast section extends in a first dimension, wherein each said gusset comprises first and second ends, wherein said first and second ends of a first plurality of said plurality of gussets are at least generally disposed in a common first plane that is orthogonal to said first dimension, and wherein said first and second ends of a second plurality of said plurality of gussets are at least generally disposed in a common second plane that is orthogonal to said first dimension and that is spaced from said first plane in said first dimension.
29. The workover rig mast of claim 1, wherein said frame comprises first, second, third, and fourth corner supports that each extend in a length dimension of said first mast section, wherein one end of each of said plurality of gussets is fixed to one of said first and second corner supports, and wherein an opposite end of each of said plurality of gussets is fixed to a corresponding one of a plurality of internally disposed cross members of said frame.
30. The workover rig mast of claim 1, wherein a maximum length for each of said plurality of gussets is 20 inches.
31. A workover rig mast, comprising:
- a first mast section comprising a frame, that in turn comprises: first, second, third, and fourth corner supports that each extend in a length dimension of said first mast section; and a plurality of gussets, wherein one end of each of said plurality of gussets is fixed to one of said first and second corner supports, and wherein an opposite end of each of said plurality of gussets is fixed to a corresponding one of a plurality of internally disposed cross members of said frame; and
- a second mast section, wherein said first mast section telescopes relative to said second mast section and extends to a higher elevation than said second mast section when in a deployed position versus a stowed position.
Type: Application
Filed: Sep 8, 2010
Publication Date: Apr 14, 2011
Inventors: Greg Wiedmer (Kenmare, ND), Thomas Edwin Mau (Kenmare, ND), Robert Eugene Mau (Kenmare, ND)
Application Number: 12/877,759
International Classification: E21B 15/00 (20060101);