The present disclosure relates generally to a machine equipped with a sideboom and a fairlead for guiding a hoisting cable to and from the sideboom, and more particularly to such a machine where the fairlead is instrumented with a cable state sensing mechanism.
Pipelayers are specialized machines used to suspend and place pipelines in a prepared trench or the like. A typical pipelayer includes a load manipulating boom positionable outwardly from the side of the machine in a direction generally perpendicular to a forward travel direction. It is common for a cable and rigging system to be provided for manipulating the position of the boom, as well as a load suspended by the boom adjacent to or within a trench. It is also typical for pipelayers to operate in teams with a group of the machines operating in a coordinated fashion, to each support a different section of pipe as the pipe is gradually placed into a trench. In some instances the pipe sections are welded together as they are suspended by the pipelayer machines. Pipelayer teams often require precise and concerted efforts not only for successful placement but also to optimize speed and efficiency and protect operators and ground crew personnel.
Due to the nature of pipeline placement and support of pipe sections out to the side of the machine, there can be challenges to stably supporting the suspended load without risking tipping the machine. These challenges can be particularly acute in poor underfoot conditions, as well as steep terrain. To enhance stability most pipelayer machines are equipped with a counterweight positioned opposite the sideboom, and which can be adjusted to compensate for adjustments in the height and positioning of a suspended load. One example pipelayer machine is known from U.S. Pat. No. 8,783,477 to Camacho et al. It will be appreciated that a significant degree of operator skill can be required to control the speed and travel direction of a pipelayer machine while also monitoring and adjusting the suspension height of the load and positioning of the supporting sideboom. The availability of skilled operators, as well as ground crew, at worksites that are often remote has long challenged the industry. For these and other reasons, continued advancements and improvements to develop and exploit technological solutions in the pipelayer field are desirable.
In one aspect, a machine includes a frame, and a hoisting system coupled to the frame and including a winch assembly. The hoisting system further includes a boom movable by pivoting between a first boom position, and a second boom position at which the boom extends outboard of the frame. The hoisting system further includes a fairlead, and a hoisting cable extending through the fairlead from the winch assembly to the boom. The fairlead is supported at a fixed orientation relative to the frame, such that a feed angle of the hoisting cable between the fairlead and the boom varies in response to the pivoting of the boom between the first boom position and the second boom position. The machine further includes a hoisting control system having a cable state sensing mechanism resident on the fairlead and structured to produce cable monitoring data indicative of at least one of a cable feed length, a cable feed angle, or a cable load, and an electronic control unit coupled with the cable state sensing mechanism and structured to output an alert based on the cable monitoring data.
In another aspect, a fairlead system for a machine includes a fairlead having a first end forming a fairlead base having a mounting surface, for mounting the fairlead to a frame in a machine, and a second end, and defining a longitudinal fairlead axis extending between the first end and the second end. The fairlead further includes a feed pulley, for feeding a hoisting cable through the fairlead between a winch assembly and a pivotable boom and the machine. A cable state sensing mechanism is resident on the fairlead and structured to produce cable monitoring data indicative of at least one of a cable feed length, a cable feed angle, or a cable load, and instrumentation circuitry for connecting the cable state sensing mechanism to an electronic control unit in a hoisting control system in the machine.
In still another aspect, a method of operating a machine includes guiding a hoisting cable between a winch assembly and a boom in the machine by way of a fairlead supported at a fixed orientation relative to a frame of the machine, and pivoting the boom between a first boom position and a second boom position relative to the frame. The method further includes producing cable monitoring data from a cable state sensing mechanism resident on the fairlead. The cable monitoring data is indicative of a change to at least one of a cable feed length, a cable feed angle, or a cable load that occurs in response to the pivoting of the boom between the first boom position and the second boom position. The method still further includes outputting an alert based on the cable monitoring data.
Referring to
Machine 10 further includes a hoisting system 24 coupled to frame 12 and including a winch assembly 26, and a boom 28 movable by pivoting between a first boom position, and a second boom position, at which boom 28 extends outboard of frame 12. Boom 28 may include a sideboom, and is pivotable about a sideboom pivot axis 29 having a fixed orientation and extending in a fore-to-aft direction relative to frame 12. Boom 28 may be oriented substantially vertically at the first boom position, and oriented approximately as shown in
Hoisting system 24 further includes a fairlead system 55 including a fairlead 56. Hoisting cable 43 extends through fairlead 56 from winch assembly 26 to sideboom 28. Fairlead 56 is supported at a fixed orientation relative to frame 12, such that a feed angle of hoisting cable 43 between fairlead 56 and sideboom 28 varies in response to the pivoting of sideboom 28 between the first boom position and the second boom position. Fairlead 56 may be positioned at a fairlead mounting location longitudinally between front frame end 14 and back frame end 16, and latitudinally between winch assembly 26 and sideboom 28. The fairlead mounting location may be both forward and outboard of operator station/cab 20. It can also be noted from
Machine 10 further includes a hoisting control system 60 having a cable state sensing mechanism 62, 64, 66, resident on fairlead 56. The cable state sensing mechanism 62, 64, 66 can include one or more sensors 62, 64, 66 structured to produce cable monitoring data indicative of at least one of a cable feed length, a cable feed angle, or a cable load. Hoisting control system 60 also includes an electronic control unit 74 coupled with the cable state sensing mechanism 62, 64, 66 and structured to output an alert responsive to the cable monitoring data.
Referring also now to
As noted above, the cable state sensing mechanism 62, 64, 66 can include one or more sensors, in one implementation a cable angle sensor 66. Electronic control unit 74 may further be structured to determine an angle of sideboom 28 based on the cable monitoring data produced by cable angle sensor 66, as further discussed herein. The cable state sensing mechanism 62, 64, 66 may additionally or alternatively include a load sensor 64, and electronic control unit 74 may be further structured to determine a hook load based on the cable monitoring data produced by load sensor 64. In a further implementation, feed pulley 82 can include a pulley pin 84, and load sensor 64 may include a strain gauge coupled with pulley pin 84. A force vector 65 is also depicted in
Referring also now to
It will also be recalled that cable feeding sensor 62 produces cable monitoring data indicative of a cable feed length through fairlead 56. In one embodiment, cable feeding sensor 62 can be structured as a rotation counter to output the cable monitoring data each time pulley 80 completes a rotation in a first direction. Cable feeding sensor 62, or another sensor (not shown), could output a cable infeed signal each time pulley 80 completes a rotation in an opposite direction. An electronic proximity sensor, an electromechanical switch, or still other strategies could be used, such as an arrangement of sensor targets on pulley 80 that are sensed to indicate rotation in one direction by way of a first pattern rotated past a sensor and indicate rotation in an opposite direction by way of a reverse pattern rotated past the sensor.
Those skilled in the art will be familiar with the phenomenon of pulley block collision, and its potential risks of straining a hoisting cable or causing other problems. A location of the normally stationary upper hook pulley block 44 in space can be determined on the basis of fixed boom geometry and sideboom angle, which is directly proportional to cable feed angle. A location of lower hook pulley block 46 can be determined on the basis of a length of hoisting cable 43 fed through fairlead 56, with a number of pulley revolutions in a feeding-out direction being proportional to a cable feed length. It will also be recalled that sensor 68 may be resident on fairlead 56. Electronic control unit 74 can receive data from sensor 68 indicative of an orientation of frame 12, and thus machine 10. Based upon the known relationship between cable feed angle and sideboom orientation, electronic control unit 74 can determine an angle of sideboom 28 relative to a horizontal reference plane or some other reference. In this general manner, electronic control unit 74 monitors orientation of hoisting cable 43 and can account for position of machine 10 upon a slope, thus determining whether there is a risk of tipping over of machine 10 when supporting a given load at least when counterweight orientation is also considered, as further discussed herein.
Referring also now to
Turning now to
Operating machine 10 can include supporting a pipeline or section of pipeline in cooperation with a plurality of other pipelayer machines. The pipelayer machines can be arranged one after the other next to a prepared trench, with each pipelayer supporting a different pipe section in a roller sling or the like. Operators, or control systems, can raise, lower, and reposition as desired the individual pipe sections to place the pipeline in the trench as the group of machines moves forward. Ground crews can assist the machines with placement, positioning, welding together of adjacent pipe sections, and other support activities. A hoisting cable such as hoisting cable 43 can be guided in each one of the machines between a winch assembly and a boom by way of an instrumented fairlead such as fairlead 56 supported at a fixed orientation relative to the frame of the associated machine.
To position the pipeline sections as desired each machine can pivot its boom between a first boom position and a second boom position relative to the frame. The cable state sensing mechanism comprised of one or more sensors as described herein, resident on the fairlead, can produce cable monitoring data indicative of at least one of a cable feed length, a cable feed angle, or a cable load. Continuous or periodic monitoring will produce cable monitoring data indicative of changes to the at least one of a cable feed length, a cable feed angle, or a cable load that occurs in response to the pivoting of the boom between the first boom position and the second boom position. For example, pivoting sideboom 28 may impart the tendency for upper hook pulley block 44 and lower hook pulley block 46 to vary their relative spacing from one another, depending upon the extent (if any) to which hoisting cable 43 is wound or unwound from winch 42. Analogously, pivoting of sideboom 28 varies cable feed angle and cable load. Based on the cable monitoring data that is indicative of changes to the parameters of interest, electronic control unit 74 can output an alert for display on display 112, for production of an audible alert, for signaling to a site manager or supervisory control system, for data recording purposes, or for still another purpose.
Referring now to
It should also be appreciated that changing a sideboom angle, for instance, can change the max allowable load and justify outputting an alert. For example, an operator might lower sideboom 28 from a first orientation where a given hook load is allowable to a second orientation where the given hook load is not allowable. In such circumstances an overload alert can be output and the operator, or control system 60, could raise sideboom 28, raise counterweight 30, adjust both sideboom 28 and counterweight 30, or take some other action. Machine underfoot conditions could also be a factor in what max allowable loads or other threshold conditions are determined and how those conditions are managed. As suggested above, changes in any of cable feed angle, cable feed length, cable load, or still other parameters can justify outputting an alert, typically, but not necessarily, because relative machine stability and/or likelihood of tipping is changed. In view of the foregoing, it will thus be appreciated that load monitoring and management of overload, pulley block collision, and other machine operating conditions according to the present disclosure can be a dynamic process.
At a block 235 is shown the strain pin, producing the load monitoring signal by way of sensor 64. At a block 240 is depicted a strain to load converter where a strain detected by way of sensor 64 is converted to a load on hoisting cable 43. The determined load on hoisting cable 43 can be converted to a current hook load according to known trigonometric or other computational or inferential techniques, for example. A load curve map is shown at a block 245. At block 245 electronic control unit 74 can compare the max allowable load to a current hook load. The load curve map might include a current hook load coordinate and a max load coordinate. An alternative strategy could include a cable load coordinate, a fairlead boom angle coordinate, a max load coordinate, and/or a counterweight angle coordinate. Still other map configurations could be used.
Several of the blocks in flowchart 200 represent information that can be displayed on display 112 to an operator. Machine angle is shown at a block 250 and can represent machine angle as determined on the basis of data from frame sensor 68. Boom angle is shown at a block 255 and can display to an operator an angle of sideboom 28 relative to a horizontal reference plane, or relative to some other reference such as frame 12. At a block 260, boom overhang is displayed. At a block 262, the max load determined at max load calculator 232 is displayed. At a block 265, the current hook load on hoisting cable 43 is displayed. Block 270 displays a percent load, meaning a percent of max allowable load that is currently applied to hoisting cable 43. At a block 272 counterweight position is displayed.
At a block 280 of program 108 is shown cable feed or cable feeding data produced by cable feed sensor 66. At a block 282 is shown a feed-to-cable length converter where, for example, a number of pulley rotations is converted to a cable length. At a block 288, it is queried whether conditions are near the 2-block limit, based on determined locations of hook blocks 44 and 46 as described herein. If no, the control routine can end or exit at a block 294. If yes, the control routine can advance to a block 299 to output an anti-2-block warning or pulley collision alert. At a block 286 electronic control unit 74 can receive the load on hoisting cable 43 and query whether conditions are near a load limit? If no, the control routine can advance to a block 292 to end or exit. If yes, the control routine can advance to a block 298 to produce the load warning or overload alert.
The present description is for illustrative purposes only, and should not be construed to narrow the breadth of the present disclosure in any way. Thus, those skilled in the art will appreciate that various modifications might be made to the presently disclosed embodiments without departing from the full and fair scope and spirit of the present disclosure. Other aspects, features and advantages will be apparent upon an examination of the attached drawings and appended claims. As used herein, the articles “a” and “an” are intended to include one or more items, and may be used interchangeably with “one or more.” Where only one item is intended, the term “one” or similar language is used. Also, as used herein, the terms “has,” “have,” “having,” or the like are intended to be open-ended terms. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
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