A drawworks apparatus is a type of winch used in the oil well drilling and service industry as a portion of a drilling or servicing rig to raise and/or lower items such as tools, equipment and lengths of pipe from a well bore from which oil or other hydrocarbons are produced.
The drawworks typically includes a large-diameter spool that typically supports a length of cable, a drive system connecting the spool to a power source, one or more brakes and other auxiliary devices that may assist in the lowering and raising items into a well bore. In certain drawworks apparatus, a band brake system having brake flanges mounted located externally on one or both ends of the drum barrel may be used to reduce the rotational speed of the drum barrel.
However, major disadvantages plague conventional drawworks designs. For instance, there is no manner in which to actively cool the brake flanges mounted. Particularly, there is no manner in which to supply a cooling fluid from a rotating union to the brake assembly.
The lack of a cooling system may lead to overheating of the brakes during operation, which in turn, will cause an inordinate amount of wear on the brakes. Such wear will reduce the operating life of the brake assembly, thereby requiring frequent maintenance to either repair and/or replace the brake flanges. Such maintenance leads to increased operating costs.
Moreover, the lack of a cooling system may lead to total mechanical failure of the brake system. Such failure may result in several undesirable consequences. For instance, brake failure during operation of the drawworks may result in the loss of tools, equipment and piping. Secondly, the brake failure will require replacement of the brakes, which, in turn, will require halting the entire drilling operation. Accordingly, the overall operating costs will significantly increase. Even still, the lack of an effective brake cooling system will inevitably reduce the amount of loads the drawworks apparatus may be able to manage due to the increased heat.
Embodiments relate to a drawworks apparatus having a cooling system for the brake mechanism.
Embodiments relate to a drawworks apparatus having a rotating union mounted on ends of the drumspool in the annulus between drum shaft and the drum barrel of the drum spool.
Embodiments relate to a drawworks apparatus having an annulus rotating union that does not contain any bearings in using adjacent bearings for supporting the drum shaft in the drum barrel.
Embodiments relate to a drawworks apparatus having an internal cooling system for effectively cooling the brake assembly during operation by dissipating heat therefrom.
Embodiments relate to a drawworks apparatus having an internal cooling system that permits heavier loads to be managed without concern for overheating.
Embodiments relate to a drawworks apparatus that utilizes an annulus rotating union having a fluid line fluidically and operatively connected to the brake assembly for supplying a cooling liquid such as water, oil and the like to the brake assembly for effectively cooling the brake assembly during operation.
In accordance with embodiments, a drawworks apparatus may include at least one of the following: a drum spool for raising and lowering items down a well bore via a length of cable wound thereon; a drum shaft which passes through and is rotatably and concentrically supported by the drum spool such that the drum shaft is isolated from wire line pull from the drum spool; a rotating union operatively connected to the drum spool and the drum shaft to permit simultaneous rotation of the drum spool and the drum shaft; a drive mechanism for rotating the drum spool; a brake assembly operatively connected to the main drum spool; and a brake cooling system extending through the rotating union, the drum shaft and the brake assembly for one of lubricating and reducing the operating temperature of the brake assembly during operation of the drawworks apparatus.
In accordance with embodiments, a drawworks apparatus may include at least one of the following: a drum spool for raising and lowering items down a well bore via a length of cable wound thereon; a drum shaft rotatably and concentrically supported by the drum spool; a first brake assembly operatively connected to the main drum spool at an on-operator side of the drawworks assembly; a second brake assembly operatively connected to the main drum spool at an off-operator side of the drawworks assembly; and a brake cooling system having including a cooling fluid line in fluidic communication with the first and second brake assemblies for reducing the operating temperature of the first and second brake assemblies during operation of the drawworks apparatus.
In accordance with embodiments, a drawworks apparatus may include at least one of the following: a drum spool; a drum shaft rotatably and concentrically supported by the drum spool; a first brake assembly operatively connected to the main drum spool at an on-operator side of the drawworks assembly; a second brake assembly operatively connected to the main drum spool at an off-operator side of the drawworks assembly; and a brake assembly cooling system for reducing the operating temperature of the first and second brake assemblies during operation of the drawworks apparatus, the brake assembly cooling system including a cooling fluid line having a first cooling fluid line portion at on-operator side of the drawworks assembly, a second cooling fluid line portion at on-operator side of the drawworks assembly and in fluidic communication with the first cooling fluid line portion, and a third cooling fluid line portion extending between and in fluidic communication with the first and second cooling fluid line portions.
Example
As illustrated in example
Drum spool 20 may be attached to drawworks frame 11 via suitable bearings in a manner permitting rotation of drum spool 20. A suitable length of cable may be wound on drum spool 20 within working area 11a of frame 11 to thereby enable drawworks 10 to raise and/or lower tools, equipment, lengths of pipe, etc. from a well bore. Drum shaft 30 is concentrically supported in drum spool 20 and extends longitudinally outward through respective shaft bores thereof.
Drum shaft 30 may be supported in a stationary manner at each end of drum spool 20 via bearings such as anti-friction bearings so as to restrict independent rotation of drum shaft 30 relative to drum spool 20. Meaning, drum spool 20 and drum shaft 30 are adapted to rotate in lock-step together. The anti-friction bearings may be mounted within the bore of drum spool 20 to support drum shaft 30 in a manner which does not restrict rotation. Accordingly, the braking ability of drawworks 10 is not adversely affected by any failure to drum shaft 30 because brake assembly 40 is structurally connected directly to drum spool 20 instead of drum shaft 30 (i.e., drum shaft 30 is structurally isolated from brake assembly 40). Thereby, drum spool 20 is supported by frame 11, and drum shaft 30, in turn, is supported by drum spool 20.
Accordingly, by arranging drum spool 20 to support drum shaft 30, any applied radial load during operation of drawworks 10 may be transmitted back to frame 11. Such a structural configuration and relationship between frame 11, drum spool 20 and drum shaft 30 is advantageous since the braking ability of the drawworks is unaffected by any failure to drum shaft 30 when drawworks 10 is effectuating a hoisting operation.
A suitable drive device may be provided for driving drum spool 20. Drum shaft 30 may support clutch 14 at one end and sprocket 15 at the other end. Thus, the torque necessary to rotate drum spool 20 is input through sprocket 15. It should be understood by those of ordinary skill that any conventional driving device known in the art may be used to drive drum spool 20.
Brake assembly 40 is provided to control the rotational speed of drum spool 20 during the operation of drawworks 10, i.e., when cable is being payed out to lower items. Brake assembly 40 may include first brake assembly 41 operatively connected to drum spool 20 and second brake assembly 42 operatively connected to drum spool 20 and distal to first brake assembly 21. First brake assembly 41 may be operatively connected to drum spool 20 at an on-operator area of drawworks 10 while second brake assembly 42 may be operatively connected to drum spool 20 at an off-operator area. Accordingly, drum spool 20 is provided with a pair of brakes 41, 42 located at each end of frame 11 outside of working area 11a. Brake assembly 40 may be a brand brake-type that is operatively connected to drum spool 20 via brake flanges 41a, 42a mounted outside working area 11a of drawworks frame 11. Such band brakes may serve to effectively reduce the rotational speed of drum spool 20, and in turn, control the rate at which the length of cable from drum spool 20 is payed out. The mounting of brake flanges 41a, 42a may be accomplished via spider 44 with keyed hub 45. In accordance with embodiments, brake flanges 41a, 42a may include a cooling fluid jacket for receiving a cooling fluid to enable such cooling fluid to be circulated throughout brake assembly 40.
Annulus rotating union 50 and rotary union 60 are provided at both ends of drum shaft 30 to enable joint rotation between drum spool 20 and drum shaft 30 during a hoisting operation of drawworks 10. Annulus rotating union 50 may be mounted in the annulus between drum shaft 20 and the drum barrel of drum spool 20. Annulus rotating union 50 does not contain any bearings since it makes use of adjacent bearings used to support drum shaft 30 in drum spool 20. When it is necessary to remove items such as tools, equipment or piping from the well bore, the clutch is disengaged permitting lock-step rotation of drum spool 20 and drum shaft 30. Cable and the traveling blocked attached thereto travels downwardly within the well bore. During this downward travel, it is necessary to have an annulus rotating union that enables a cooling fluid to circulate to the jacketed brake flanges 41a, 42a.
Rotary union 60 may be received into hole placed axially at the distal end of drum shaft 30. Such a hole may be threaded in order that corresponding threads of rotary union 60 may be received by screwing rotary union 30 into the hole. The hole may be formed at a depth to permit a second hole to be formed in drum shaft 30 extending perpendicular with respect to the first hole. From an axial perspective, the second hole may be located within an inner diameter of the drum barrel.
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In fluidic communication with cooling fluid passage 21a is gland 52, which receives the cooling fluid therefrom. Gland 52 is in fluidic communication with pipe adapter 53a which is received by gland 52 in order to permit circulation of the cooling fluid therethrough. The cooling fluid flows through pipe adapter 53, into hose 54a and then into the cooling fluid jacket of brake flange 41a. In accordance with embodiments, the water jacket of brake flanges 41a, 42a are designed in a manner to permit full circulation of the cooling fluid therethrough in order to cool (i.e., reduce the temperature) the surfaces of the brake flange 41a.
The cooling fluid exits the brake flange 41a through hose 54b and flows through pipe adapter 53b and into pipe manifold 55 which is interposed between and extends parallel to drum spool 20 and drum shaft 30. The cooling fluid flows from pipe manifold 55 and enters a cooling fluid passage in drum spool 20 at the off-operator side of drawworks 10. The cooling fluid exits drum spool 20 and flows through pipe adapter 53c, hose 54c and enters the cooling fluid jacket of brake flange 42a. As with the on-operator side of drawworks 10, the cooling fluid circulates through the cooling fluid jacket therethrough in order to cool (i.e., reduce the temperature) the surfaces of the brake flange 42a.
The cooling fluid exits the brake flange 42a and flows sequentially through hose 54d, pipe adapter 53d and gland 52 where it enters cooling fluid hole 21b of drum spool 20. From cooling fluid hole 21b the cooling fluid flows into the circulating chamber formed by spring-loaded lip seal which rides on seal spacer 57 and mounted in seal carrier. The cooling fluid exits the circulating chamber and enters the cooling fluid passage groove of seal spacer through a plurality of holes. From the cooling fluid passage groove, the cooling fluid enters the cooling fluid passage hole 31b of drum shaft 30 and then passes through rotary union 60 where it then flows into a cooling fluid storage chamber or cooling fluid supply.
In order to provide a visual indication of when maintenance should be performed on seals, weep holes 70, 71 are provided at the on-operator and off-operator regions of drawworks 10. Drain or weep holes 70, 71 permit the drainage of the cooling fluid instances where seal leakage occurs. Such drainage indicates than one or more seals should be maintained and/or replaced. As illustrated in example
In accordance with embodiments, rotating union 60 may include seal spacer 51 mounted on drum shaft 30 and gland mounted on the extended drum barrel of drum spool 20, at least one of gland arrangement 52, 62 and seals installed in the gland arrangement 52, 62 with a sealing surface running on the seal spacer 51. The sealing surface of seal spacer 51 may be composed of an elastomeric material. Accordingly, rotating union 60 in accordance with embodiments routes cooling fluid from a drilled hole in drum shaft 30 to a cooling fluid passage in drum spool 20.
In accordance with embodiments, a drawworks having an annulus rotating union mounted on ends of the drum spool may be equipped with an internal brake cooling system that circulates a cooling liquid such as water, oil and the like to the brake assembly for effectively cooling the brake assembly during operation prevents. Such a cooling system prevents overheating of the brake assembly. Accordingly, the drawworks is capable of handling heavier loads without concern for overheating of the brake assembly. Such features may thereby significantly reduce overall operating and maintenance costs.
Although embodiments have been described herein, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
This application claims the benefit of U.S. Provisional Application Ser. No. 61/189,214, filed Aug. 18, 2008.
Number | Date | Country | |
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61189214 | Aug 2008 | US |