The invention relates generally to the field of drilling and processing of wells, and, more particularly, to a top drive with mounted winch for hoisting drilling equipment.
In conventional oil and gas operations, a well is typically drilled to a desired depth with a drill string, which includes drillpipe, drill collars and a bottom hole drilling assembly. The drill string may be turned by a rotary table and kelly assembly or by a top drive. A top drive typically includes a quill, which is a short length of pipe that couples with the upper end of the drill string, and one or more motors configured to turn the quill. The top drive is typically suspended from a traveling block above the rig floor so that it may be raised and lowered throughout drilling operations.
In conventional operations, to add a length of tubular (i.e., drillpipe or drill collar) to the drill string, a drillpipe elevator is coupled with the tubular to facilitate hoisting the tubular from the rig floor and into engagement with a top drive, which is used to couple the tubular to the drill string. To facilitate coupling of the tubular with the top drive, the tubular is aligned with the quill of the top drive and, consequently, with the center of the well. Drillpipe elevators are configured to couple with drillpipe by engaging a shoulder of a tool joint of the drillpipe. However, drillpipe elevators are generally not configured to couple with drill collars because drill collars do not include tool joints. Therefore, pickup subs are typically connected to one end of a drill collar to facilitate coupling between a drillpipe elevator and the drill collar. After a new length of drill collar is hoisted to the center of the well by the drillpipe elevator and added to the drill string, the pickup sub is removed from the drill collar and connected to the next length of drill collar to be hoisted by the drillpipe elevator.
In addition to tubular, it may be desirable to hoist other drilling equipment (e.g., top drive servicing equipment) toward the top drive quill throughout drilling operations. This equipment may not be configured to couple with a drillpipe elevator directly and, therefore, may require specific connectors to facilitate coupling with the drillpipe elevator. In conventional operations, drilling equipment and tubular may be hoisted with wire cables on pulleys positioned about the drilling rig, and in certain instances multiple pulleys may be used in order to bring a single piece of equipment or tubular into alignment with the quill of the top drive.
The process of coupling and removing connectors in order to add each new length of tubular to the drill string or to position equipment in alignment with the top drive is often time consuming and tedious. In addition, the use of wire cables on pulleys positioned about the oil rig to hoist drilling equipment can lead to cable entanglements. Accordingly, it is now recognized that these hoisting techniques are inefficient and there exists a need for a system and method for hoisting drilling equipment into alignment with the quill of the top drive without the use of connectors or multiple pulley arrangements.
Present embodiments are designed to respond to such a need. In accordance with one aspect of the invention, a top drive system comprises a housing, a quill configured to couple with a tubular or well equipment, a motor disposed within the housing that rotates the quill, and a winch coupled with the housing. The winch comprises a motorized spool and a flexible line, which extends through a channel in the quill and includes an attachment feature at its distal end configured to couple with the tubular. As the winch winds the flexible line about the spool, the extended portion of the flexible line shortens, pulling the tubular toward the quill.
Present embodiments also provide a method for bringing well equipment into alignment with the top drive quill. In an exemplary embodiment, the method comprises coupling a tubular and a flexible line that extends from a winch on a top drive, drawing the tubular toward the top drive by winding the flexible line onto the winch, pulling the flexible line through a channel of a quill of the top drive, and aligning the tubular with a coupling feature of the quill as the flexible line is drawn into the channel.
In accordance with another aspect of the invention, a top drive system comprises a quill configured to couple with a tubular, a motor to rotate the quill, a winch with a flexible line and a spool, and an attachment feature at the distal end of the flexible line configured to couple with a tubular. The flexible line may be retracted onto the spool, drawing the line through a channel in the quill and bringing the tubular, which is coupled to the attachment feature, into alignment with the quill for coupling with the quill.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
The present disclosure provides a novel top drive system and method that can be used in drilling operations. The presently disclosed techniques allow for tubular or drilling equipment to be brought to well center using a top drive with a mounted winch. The winch supplies a flexible line that extends through the quill of the top drive on which the winch is mounted. The flexible line is coupled to an attachment feature configured to couple with various types of tubular (e.g., drill collar) or drilling equipment (e.g., top drive servicing equipment). Winding the flexible line about the winch hoists the tubular or equipment into alignment with the top drive quill and, consequently, the center of the well.
Turning now to the drawings,
It should be noted that the illustration of
Furthermore, the utility of present embodiments is not limited to hoisting tubular 38, which is the function illustrated in
The gooseneck 56 of the top drive 40 is fixed or stationary with respect to the top drive housing 54 and features a curved neck portion with a first channel 60 for conveying drilling fluid from a pressurized hose to the top drive 40 during drilling operations. A vertically aligned linear body portion of the gooseneck 56 includes a second channel 62 that joins the first channel 60 within the gooseneck and aligns with the quill 46. The quill 46 features threads 64 configured to couple the quill 46 with tubular 38 so that the top drive 40 may turn the drill string 28 while advancing the drill string 28 down the wellbore 30. In other embodiments, different coupling features may be employed. In addition to threads 64, the quill 46 features a channel 66 through which drilling fluid may flow into the drill string 28. The wash pipe 58 features a channel 68 and connects the stationary gooseneck 56 to the quill 46, acting as a conduit for drilling fluid between the rotating and non-rotating components of the top drive 40.
In addition to the above mentioned components of the top drive 40, the winch 42 is mounted to the top drive housing 54 in accordance with present embodiments. The winch 42 includes a spool 70 and the flexible line 44 disposed about and extending from the spool 70. The flexible line 44 may be wound onto or released from the spool 70 as a motor coupled or integral with the winch 42 turns the spool 70. The flexible line enters the second channel 62 of the gooseneck 56 and extends through the wash pipe channel 68 and the quill channel 66, exiting the top drive 40 through the bottom of the quill 46. At the distal end of the flexible line 44 is an attachment feature 72 configured to engage with drilling equipment (e.g., the tubular 38 shown in
It is important to note that top drives vary widely in design, size, application, and compatibility with certain drilling equipment, as will be appreciated by those skilled in the art. For example, a top drive designed for use on a small, truck-mounted drilling rig may be unable to support the same loads of a top drive designed for use on an offshore drilling rig. Despite such differences in size and design, top drives typically include the gooseneck 56, the wash pipe 58, and the threaded quill 46, and these features are generally arranged such that the second channel 62 of the gooseneck 56 aligns with the wash pipe channel 68 and the quill channel 66. These connected channels not only allow drilling fluid to travel through the top drive 40, but provide a channel for the flexible line 44 to extend through the top drive 40. Therefore, in accordance with present embodiments, the exemplary top drive 40 described herein may be achieved by retrofitting a range of top drive designs currently in use on drilling rigs.
In addition to the prongs 76, the grapple head 74 comprises an auto release latch 78 configured to extend the prongs 76 when the tension on the flexible line 44 exceeds a threshold. This tension threshold may be set such that the prongs 76 remain extended and hooked under the tubular 38 as the weight of the tubular 38 contributes a corresponding tension to the flexible line 44. The threshold may be significantly lower than the force contributed by the mass of the tubular 38 or well equipment acted on by gravity. The auto release latch 78 is also configured to collapse the prongs 76 of the grapple head 74 when the tension on the flexible line 44 drops below the tension threshold. Many scenarios may cause the release in tension that leads to the auto release latch 78 collapsing the prongs 76. For example, the tubular 38 may be pulled into engagement with the quill 46 of the top drive 40, and once the connection is made via the threads 58 on the quill 46, the winch 42 may unwind the flexible line 44. Due to the coupling between the quill 46 and the tubular 38, the slacked flexible line 44 no longer supports the weight of the tubular 38 and the tension drops below the threshold. The auto release latch 78 enables the attachment feature 72 to engage or disengage with the tubular 38 without the addition or removal of special connecting pieces (e.g., the pickup sub mentioned previously), increasing the efficiency of the drilling process.
A second embodiment of the attachment feature 72 is illustrated in
Other embodiments of the attachment feature 72 illustrated in
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
This application claims priority from and the benefit of U.S. Provisional Application Ser. No. 61/555,849, entitled “Top Drive With Mounted Winch,” filed Nov. 4, 2011.
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