Embodiments of the present disclosure generally relate to apparatuses for, and methods of, facilitating transfer of objects using a crane.
Ship-to-Ship Transfer (STS) operations are the transfer of cargo between seagoing ships positioned alongside each other, either while stationary or underway. This operation is typically performed utilizing a lifting device, usually a crane. As this operation is typically performed in the middle of the sea, the weather and sea state will cause both vessels to surge, sway, heave, pitch, yaw, and roll. Typically, both vessels are separated from each other and a relative horizontal distance therebetween is maintained using, for example, dynamic positioning, anchors, or ropes, among other devices. As such, the dynamic motions of each vessel are independent from one another.
While most dynamic movements can be controlled by providing a “safe zone” around the lifted product (e.g., adequate spacing to avoid inadvertent collisions), the vertical movement is still significant and thus can lead to hazardous situations when a load slams back to a vessel deck due to relative vessel movement. This “load slamming” can result in damage to the load/product and/or vessel. Due to this, STS operations are typically limited to favorable weather conditions to reduce the risks. In cases of unfavorable weather conditions which prevent STS operations, the cost of a particular operation is driven upwards due to both vessels being in stand-by until conditions improve to allow the operations to commence.
“Load slamming” risk is currently mitigated in some restricted cases by using a constant tension mode of the crane wherein a sensor is used to detect change in tension of the cable and reacts to maintain tension at a constant or near constant value. However, this feature is only available on some cranes and is limited to specific use cases and limited capacities.
Another conventional method of managing load slamming uses a derating chart to limit the load capacity of offshore cranes due to relative velocities between the crane vessel and the deck of a supply vessel or barge. The relative velocities are derived by wave height and the allowed loads are typically conservative, particularly since wave heights are often estimated visually by an operator, and therefore, not precise. A conventional derating chart, as shown in
Other conventional techniques use active heave compensators (AHC) to address the relative motion between vessels. An AHC is a device used to compensate hook elevation according to real time calculation of motions collected from a motion reference unit (MRU) sensor located on each vessel. However, such techniques require the MRU sensors be installed on each vessel and information must be transmitted wirelessly therebetween. Such wireless data links are prone to interruption which reduces the reliability of the wireless MRU systems. Therefore, wireless MRU sensors are not able to reliably address the “load slamming” risk discussed above.
Therefore, what is needed is a new method and apparatus for facilitating transfer of objects with cranes, including but not limited to real time relative motion measurement for derating of the crane for load lifting operations.
Aspects of the disclosure include apparatus for, and methods of, facilitating transfer of objects using a crane. Disclosed apparatuses include a target tracking device mounted on or near a crane at a first location, and a target located near a landing location for the object. The target tracking device and the target facilitate real time determination of relative motion between the two locations. Methods of using the same are also disclosed.
In one aspect, a method of performing a landing or lift-off operation between a first vessel having a crane thereon and a second vessel is provided. The method includes tracking a target located on the second vessel with a target tracking device positioned on the first vessel; determining a relative motion between the first and second vessel based on data produced by the target tracking device; and compensating for the relative motion between the first vessel and the second vessel in response to the data produced by the target tracking device.
In one aspect, a method of performing a landing or lift-off operation between a first vessel having a crane thereon and a second vessel is provided. The method includes tracking a target located on the second vessel with a target tracking device positioned on the first vessel; in response to the tracking, producing data that indicates: a distance between the target tracking device and the target; and a relative angle between a vertical axis and a line of sight between the target tracking device and the target; determining a relative motion between the first and second vessel based on the data produced by the target tracking device; and determining a lifting capacity of the crane based on the relative motion.
In another aspect, a system for performing a landing or lift-off operation includes a crane having an active heave compensator coupled thereto; a target tracking device; an optical target, the optical target configured to be tracked by the target tracking device; and a controller, the controller configured to receive data from the target tracking device, and in response to receiving the data, send instructions to the active heave compensator to provide active heave compensation.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only exemplary embodiments and are therefore not to be considered limiting of scope, as the disclosure may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
Aspects of the disclosure include apparatus for and methods of facilitating transfer of objects using a crane. Disclosed apparatuses include a target tracking device mounted at a first location, and a target located near location for the object to be lifted from or landed onto. The target tracking device and the target facilitate real time determination of relative motion between the two locations. Methods of using the same are also disclosed.
To facilitate transfer of the object 103 by accounting for relative motion between the first vessel 102 (and thus, the crane 100) and the second vessel 104, a target tracking device 110 is utilized. The target tracking device 110 is an instrument that accurately measures the position of an optical target 111, which may be positioned on or adjacent to an object, such as object 103. The target tracking device 110 is generally mounted on the cab 105 of the crane 100 but other mounting locations, such as on the deck, may be used. The optical target 111 is mounted on the second vessel 104 near the object 103 (or near a location at which the object 103 is to be positioned). Thus, as the target tracking device 110 tracks the optical target 111, tracking of the second vessel 104 relative to the target tracking device 110 (and correspondingly, the crane 100 and the vessel 102) occurs. In one example, the optical target 111 is a spherically mounted retroreflector (SMR), which resembles a ball bearing with mirrored surfaces formed thereon. In another embodiment, the optical target 111 is an optical grid of alternating squares which are recognizable by the target tracking device 110. It is to be noted that other shapes, such as triangles or circles, which are distinguishable by the target tracking device 110 may be utilized for the optical grid. Further, the optical target 111 may also be a different type of marker which is recognizable by the target tracking device 110.
The target tracking device 110 is configured to determine a distance between the target tracking device 110 and the optical target 111. In addition, the target tracking device may also simultaneously determine an angle of a line of sight (e.g., a direct line between the target tracking device 110 and the optical target 111) relative to a vertical axis of the operator cab 105 or other reference axis.
In one example, servo motors within the target tracking device 110 continuously orient the target tracking device 110 towards the optical target 111 in response to relative movement therebetween. A trigonometric calculation is performed to calculate the height of the object 103 above the optical target 111 and the distance therebetween. The determination of the distance between the target tracking device 110 and the optical target 111, the distance between the object 103 and the optical target 111, and the angle of the line of sight of the target tracking device 110 to the optical target 111 relative to an axis, such as the axis of the cab 105, are used to determine relative motion between the first vessel 102 and the second vessel 104.
In another example, the target tracking device 110 determines a distance between the shapes of an optical grid used as the optical target 111. The shapes are distinguishable by the target tracking device 110. The distance between the shapes, or the sizes thereof, is used by the target tracking device 110 to determine distance therefrom. For example, a distance between the shapes may be known. The target tracking device 110 is configured to measure a distance between the shapes and relate the measured distance between the shapes to the known distance therebetween to determine the distance of the optical target 111 from the target tracking device 110.
The target tracking device 110 may also determine a rotational motion of the optical target 111. In one example, the target tracking device 110 determines relative rotation of the optical target 111 by determining distances between the objects used to form the optical grid of the optical target 111 and/or image matching images of the said optical grid to images of optical grids of a known relative rotation. The determined rotational motion of the optical target 111 can be used to determine the rotation of an object offset therefrom, such as the load 103 or a landing area on the deck of a vessel.
Processing of data, including performance of calculations, is performed by a controller 115 or other computing device. In one example, the controller 115 is located within the operator cab 105 and displays information to the operator on a display. The display may optionally be a touch-screen panel, allowing an operator to interact with the display, the controller 115, and the target tracking device. In yet another example, display may be a heads-up display (HUD).
The target tracking device 110 and the optical target 111 allow the relative velocity (e.g., a change in the measured position over a period of time) between the first vessel 102 and the second vessel 104 to be determined. The determination of relative velocity allows assessment as to whether the motion between the first vessel 102 and the second vessel 104 is within a specified operational range corresponding to particular lift, such as a given load and size thereof, thereby improving safety. Additionally, the relative velocity and/or the relative motion between the first vessel 102 and the second vessel 104 can be used to determine a derating factor of a crane and a lifting capacity thereof based upon to the relative motion.
Traditionally, heave compensators and associated systems act on the hoist or a cylinder in reeving of the hoist line 108. With reference to
It is to be noted that the target tracking device 110 may determine relative motion between the first vessel 102 and the second vessel 104 without active heave compensation being applied. For example, the target tracking device 110 can determine relative motion between the vessels to aid an operator in determining a derating factor of the lifting capacity of the crane 100 in relation to the determined relative motion. The derating factor may be determined by a control system automatically or may be determined by an operator using a derating chart based upon relative velocity and/or relative motion. Additionally, although the crane 100 and the vessel 102 are located in water, it is contemplated that the crane 100 may alternatively be located onshore or on a fixed offshore structure. In such examples, the crane 100 may be mounted on a mobile platform, such as a truck or a quay, or may be fixed in position. The crane 100 may also be mounted to a jack-up crane barge, a jack-up offshore platform, or a floating offshore platform.
It is also contemplated that targets other than the optical target 111 may be utilized according to implementations of the present disclosure. The optical target 111 may include other reflective materials, or may vary in size, quantity, and shape.
In other aspects, it is contemplated that more than one optical target may be utilized. In such an example, a second optical target, such a laser or an optical grid, can be output from additional sources with signatures, such as wavelengths or grid patterns, identifiable by the target tracking device 110. Such a configuration may be useful when an optical target 111 is to be placed in a hazardous environment, such as an area under a hanging load (e.g., directly beneath the object 103 during landing or lift-off). According to this embodiment, a person located on a working deck, such as the deck of the second vessel 104 could use an optical target source, such as a laser pointer, to direct the target tracking device 110 onto an optical target (e.g., the operator could “paint” a target to be recognized by the target tracking device 110). Once the target tracking device 110 recognizes the optical target, the position of the optical target is registered for future tracking by the target tracking device 110 and for viewing in a display of the operator cab 105. In another embodiment, the second target may be a series of coordinate points input into the system which are recognizable by the target tracking device 110.
Once a target is registered, the target can be stored by the memory of the system and thus does not require continued illumination with the laser pointer by an operator. For example, the target may be stored as an image to be image matched by the controller. Thus, the targets can be stored for operations beyond the immediate lift-off or landing operation. In doing so, the stored targets (viewable on a crane operator display, such as an HUD) may provide visual landmarks to which a crane operator can navigate the crane hook 109 or an object 103 suspended therefrom. Thus, the hook 109 can be guided into positions normally not navigable, or at least unnavigable without a likelihood of inadvertent collision between the hook 109 and surrounding items. The hook may be guided into a desired position manually, semi-manually (i.e., computer assisted), or autonomously. It is contemplated that such functionality is beneficial to and applicable to both offshore operations and operations where one or both of the crane 100 or the object 103 is located onshore or on a platform. Thus, while methods and apparatus are described herein in context to offshore operations, onshore operations are also contemplated.
The target tracking device 210 includes a base 220, a rotating mount 221, and an optical unit 222. The base 220 is configured to be mounted on a surface, such as the operator cab 105 of a crane 100. The rotating mount 221 is mounted on the base 220 and rotates about a vertical axis Z. The optical unit 222 is positioned within the rotating mount 221, and rotates therein about an axis X. The optical unit 222 includes a laser-generating source (not shown) therein which projects a laser 223 toward the optical target 111. The target tracking device 210 adjusts the relative positions of the rotating mount 221 and an optical unit 222 to continuously direct the laser 223 at the optical target 111 in response to movement therebetween. The laser 223 is reflected from the optical target 111, such as a spherically mounted retroreflector (SMR), and received by the optical unit 222 to facilitate determination of distance between the target tracking device 210 and the optical target 111. The optical unit 222 may also house one or more instruments therein, such as an accelerometer and/or an encoder, to determine a relative angle between the laser 223 and the vertical axis Z (or another axis). Information such as relative angle and distance to the optical target 111 are provided to a controller, such as controller 115, to perform calculations for active heave compensation or other operations.
In certain embodiments, the optical unit 222 of the target tracking device 210 may be replaced with an optical viewer, such as a camera system, which is configured to recognize the optical target 111. The target tracking device 210 may also use a combination of laser tracking and camera systems.
In one example, the target tracking device 210 has an optical viewer with a defined field of view. The optical target 111 is maintained in the field of view of the target tracking device 210. The relative position of the optical target 111 within the field of view of the target tracking device 111, and the changes in relative position of the optical target 111 over a period of time, are used by the target tracking device 210 to determine the relative motion between the first vessel and the second vessel and/or distance of the optical target 111 from the target tracking device 210. In a further example, two target tracking devices 210 with optical viewers are used. Each target tracking device 210 is directed towards the optical target 111. A controller compares the detected image from each target tracking device 210 to determine distance of the optical target 111 from the target tracking devices and/or relative motion of the optical target 111.
In one aspect, data obtained by the target tracking device 110 is compiled and combined with other information from crane metrologies. In one example, the data obtained by the target tracking device 110 is compiled and combined with rope payout, boom angle, relative location of the carriage, or other data. The HUD is also configured to visually illustrate the ideal time to start a lifting or landing operation of the object 103 on the second vessel 104, or to direct operator control input, or to illustrate motion caused by the active heave compensator. The HUD may also display available hook height at a given location.
With reference to
For example, using aspects described herein, the relative velocity of both vessels can be accurately derived, thereby mitigating excessive derating by eliminating inaccurate visual estimates of wave heights or relative motions used in conventional methods. Moreover, using aspects described herein, relative motions are updated on a real-time basis, further ensuring operational windows are not exceeded due to changing atmospheric conditions but while still allowing operations to be performed at an upper boundary of an operational window.
In another embodiment, the target tracking device 110 is coupled to a laser indicator. The target tracking device 110 may irradiate a position, such as a landing location of a load, with the laser indicator for personnel to mark the position, such as locations 660. The locations 660 may be determined by the system as described above or coordinate points input into the system by an operator. Indicating such positions decreases the time necessary for personnel to manually measure locations using conventional means, such as, to determine the landing location of a load.
In addition, as described above, when ascertaining a distance from the crane 100 to a location 660, a display, such as the HUD 440b shown in
Benefits of aspects described herein include broadening of the “time-window” of favorable weather by allowing the crane to compensate dynamic vertical movement of both vessels. Thus, vessels using aspects described herein can operate in windows that are otherwise inoperable by conventional techniques. Additionally, the measurement systems described herein provide relative velocity that can be used as an assessment tool as to whether the motions between vessels are too great to perform a lift. Moreover, the determination of relative velocity allows a more specific selection of a derating curve, which conventionally required operators to use estimation. The estimation of operators in conventional techniques either did not allow utilization of full crane potential (by over-estimating relative velocity between vessels) or put operators in an unsafe operating window (by underestimating relative velocity).
Aspects of the disclosure provide additional advantages over conventional approaches. For example, by positioning a target tracking device on the operator cab, the target tracking device is able to track an optical target, and maintain the line of sight to the optical target even during a lift-off operation. The position of the target tracking device according to aspects described herein facilitates continued monitoring and determination of relevant motion between vessels throughout a lift-off operation. Therefore, if a lifted object and the vessel from which the object is lifted are in a state which cause “load slamming” the two to “slam” into one another during the lift, an alert can be provided to operator to address the situation, or alternatively, AHC may be employed, in response to target tracking measurements, to avoid a “slam” situation.
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application claims benefit of U.S. provisional patent application Ser. No. 62/464,942, filed Feb. 28, 2017, which is herein incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
3799505 | Duncan | Mar 1974 | A |
4147330 | Eik | Apr 1979 | A |
6115129 | Holmquist et al. | Sep 2000 | A |
6182843 | Tax et al. | Feb 2001 | B1 |
6826452 | Holland | Nov 2004 | B1 |
8681317 | Moser et al. | Mar 2014 | B2 |
9041595 | Cameron | May 2015 | B2 |
9815668 | Morath | Nov 2017 | B2 |
9849944 | Foo | Dec 2017 | B2 |
9902596 | Morrow et al. | Feb 2018 | B2 |
10308327 | Van Loon | Jun 2019 | B1 |
20060191457 | Murphy | Aug 2006 | A1 |
20070050115 | Discenzo | Mar 2007 | A1 |
20070289931 | Henriksson | Dec 2007 | A1 |
20080229524 | Watchorn | Sep 2008 | A1 |
20120296519 | Eberharter | Nov 2012 | A1 |
20130120577 | Austefjord | May 2013 | A1 |
20130154869 | Cameron et al. | Jun 2013 | A1 |
20130245817 | Schneider | Sep 2013 | A1 |
20130345857 | Lee | Dec 2013 | A1 |
20140107971 | Engedal | Apr 2014 | A1 |
20140284296 | Appels | Sep 2014 | A1 |
20150112638 | Morrow | Apr 2015 | A1 |
20150360887 | Maij | Dec 2015 | A1 |
20150375836 | van der Tempel | Dec 2015 | A1 |
20160063709 | Booij | Mar 2016 | A1 |
20160376848 | Taraldrud | Dec 2016 | A1 |
20170096196 | Foo | Apr 2017 | A1 |
20170120991 | Wallin | May 2017 | A1 |
20180312225 | Peleg | Nov 2018 | A1 |
20180370775 | Gong | Dec 2018 | A1 |
Number | Date | Country |
---|---|---|
104370229 | Aug 2016 | CN |
2163402 | Feb 1986 | GB |
S5953394 | Mar 1984 | JP |
H1036071 | Feb 1998 | JP |
2013147173 | Aug 2013 | JP |
2016-193706 | Nov 2016 | JP |
10-2015-0027105 | Mar 2015 | KR |
2010009570 | Jan 2010 | WO |
2013015684 | Jan 2013 | WO |
2015044898 | Apr 2015 | WO |
2015087074 | Jun 2015 | WO |
2018228809 | Dec 2018 | WO |
Entry |
---|
PCT/US2018/020203, International Search Report dated May 8, 2018, 3 pages. |
Australian Examination Report dated May 7, 2020 for Application No. 2018227805. |
Tordal, Sondre Sanden et al., “Relative Vessel Motion Tracking using Sensor Fusion, Aruco Markers, and MRU Sensors,” Modeling, Identification and Control, vol. 38, No. 2, pp. 79-93. |
Chinese Office Action dated May 7, 2020 for Application No. 201880014145.3. |
International Search Report and Written Opinion dated Aug. 5, 2020 for Application No. PCT/US2020/016527. |
Australian Examination Report dated Jul. 8, 2020 for Application No. 2018227805. |
Chinese Office Action dated Jan. 29, 2021 for Application No. 201880014145.3. |
Canadian Office Action dated Sep. 21, 2020 for Application No. 3,053,477. |
Korean Office Action dated Feb. 3, 2021 for Application No. 10-2019-7025837. |
Australian Examination Report dated Oct. 19, 2020 for Application No. 2018227805. |
Japanese Office Action dated Oct. 20, 2020 for Application No. 2019-547416. |
Australian Examination Report dated Mar. 23, 2021 for Application No. 2018227805. |
European Office Action dated Apr. 22, 2021 for Application No. 18710697.6. |
Australian Notice of Acceptance dated May 12, 2021 for Application No. 2018227805. |
Number | Date | Country | |
---|---|---|---|
20180244505 A1 | Aug 2018 | US |
Number | Date | Country | |
---|---|---|---|
62464942 | Feb 2017 | US |