The present invention relates to the field of seismic exploration. More particularly, the invention relates to a deck configuration for an ocean bottom seismometer launch platform and most particularly, the invention relates to a deck configuration that enhances the handling and manipulation of the multiplicity of ocean bottom seismometers that are typically deployed and retrieved in deep marine seismic exploration operations.
Seismic exploration operations in marine environments typically are conducted from the deck of one or more seismic exploration vessels, such as floating platforms or ships. While the fundamental process for detection and recording of seismic reflections is the same on land and in marine environments, marine environments present unique problems due to the body of water overlaying the earth's surface, not the least of which is moving personnel and equipment to a site and maintaining them there for an extended period of time. In this same vein, even simple deployment and retrieval of seismic receiver units in marine environments can be complicated since operations must be conducted from the deck of a seismic exploration vessel where external elements such as wave action, weather and limited space can greatly effect the operation.
These factors have become even more significant as exploration operations have moved to deeper and deeper water in recent years, where operations require longer periods of time “at sea.” Among other things, exploration in deep water has resulted in an increased reliance on seismic receiver units that are placed on or near the seabed. These devices are typically referred to as “OBC” (Ocean Bottom Cabling) or “OBS” (Ocean Bottom Seismometer) systems. Most desirable among these ocean bottom systems are OBS system known as Seafloor Seismic Recorders (SSR's). These devices contain seismic sensors and electronics in sealed packages, and record seismic data on-board the units while deployed on the seafloor (as opposed to digitizing and transmitting the data to an external recorder). Data are retrieved by retrieving the units from the seafloor. SSRs are typically re-usable.
In a typical operation, hundreds if not thousands of OBS units are deployed in a seismic survey. For SSRs, these units must be tracked, charged, deployed, retrieved, serviced, tested, stored and re-deployed all from the very limited confines of the deck of the surface vessel. Because of the large number of OBS units that must be handled, additional surface vessels may be employed. Additional surface vessels are costly, as are the personnel necessary to man such vessels. The presence of additional personnel and vessels also increases the likelihood of accident or injury, especially in deep water, open-sea environments where weather can quickly deteriorate.
One particular problem that arises in offshore seismic operations is the manipulation and movement of these OBS units on a vessel's launch/recovery deck when weather and ocean conditions are onerous. Typically an overhead crane on a vessel's deck is utilized to grasp and move equipment from one location to another, such as moving OBS units from a storage area to a launch area. These cranes are generally tower cranes that must lift a load relatively high above the deck in order to clear other equipment and structures on the deck. However, those skilled in the art understand that as such equipment is lifted clear of the deck, it will have a tendency to swing on the gantry's lifting line, which can create a safety hazard. This is especially problematic for a vessel operating in rough seas or windy conditions. In such cases, operations may have to be suspended until they can be conducted without endangering personnel, equipment or both.
Nowhere in the prior art is there described a launch/recovery deck system for handling the above-described OBS units, ancillary equipment and operations, whether it be storage of the units or deploying and retrieving the units or any other equipment associated therewith, such as Remote Operated Vehicles (“ROVs”) that might be used in the operations. As the size of deep water seismic recorder arrays becomes larger, a system for efficiently and safely storing, tracking, servicing and handling the thousands of recorder units comprising such an array becomes more necessary.
Thus, it would be desirable to provided a system on the deck of an OBS deployment/retrieval vessel for efficiently handling the hundreds or thousands of OBS units that can comprise an array. Such a system should permit the safe handling and efficient movement of OBS units and their storage containers along the deck, even under adverse weather or ocean conditions. Such a system should facilitate the deployment, retrieval, tracking, maintenance and storage of OBS units, while minimizing manpower and the need for additional surface vessels. The system should likewise minimize potential damage to the individual units during such activity.
The present invention provides a unique, efficient and safe configuration for the deck of an OBS deployment marine vessel, wherein parallel and perpendicular travel paths for movement of OBS unit storage baskets are formed along a deck utilizing, in part, the storage baskets themselves. More specifically, a portion of the deck is divided into a grid defined by a series of perpendicular and parallel rails and each square in the grid is disposed for receipt of a storage basket in which a plurality of OBS units are housed. The height of the rails need only be sufficient to prevent a storage basket seated within a grid square from shifting. Around the perimeter of the grid is an external containment wall which has a greater height than the rails. Storage baskets seated within the grid form internal containment walls within the grid. An overhead gantry is disposed to move over the top of the grid. The external containment walls and internally formed storage basket containment walls are positioned to form travel paths through which the overhead gantry can move individual baskets. The gantry need only lift a basket a sufficient height to clear the height of the rails defining the grid square in which the basket is seated, which is preferably only several inches. As a basket is moved through the grid along a particular travel path from its storage location to a servicing location, uncontrolled swinging of the basket is inhibited by the containment wall and the “wall” formed by the other containment baskets. Furthermore, since the basket need only be lifted inches above the deck itself in order to be moved through the grid, uncontrolled swinging is also prevented by the deck itself since the width and depth of the basket are much greater than the height of the basket above the deck. In another embodiment of the invention, poles or similar structures may be utilized to form a part of the travel path for movement of individual storage baskets when the desired travel path is not adjacent external and internal containment walls.
The travel paths formed by the internal walls, the external walls and the poles permit storage baskets to be moved from a storage location within the grid to various stations for OBS unit charging, data extraction and maintenance, as well as stations where the individual OBS units can be moved between the storage basket and a deployment/retrieval vehicle or mechanism. In one embodiment of the invention, each storage basket contains a plurality of seats for receipt of OBS units. Each seat is disposed to orient an OBS unit disposed therein for various servicing activities such as seismic data retrieval, charging, testing, and synchronization.
With reference to
Defined on deck 18 is a storage area 24 for storage of baskets 22. Preferably positioned within storage area 24 are stations 21 at which OBS units 20 can be manipulated for various desired purposes. For example, it may be desirable to provide a station for extracting data from OBS units 22 once they have been retrieved from ocean floor 14. In the illustration of
Storage area 24 is characterized by a grid 26 formed by a series of spaced apart perpendicular and parallel rails 28 that define cells or seats 30. For purposes of reference, grid cells 30 are aligned along an x-axis 25 and a y-axis 27 to form a plurality of x-axis rows 29 and a plurality of y-axis rows 31. Each grid cell 30 is disposed for receipt of a storage basket 22. In the preferred embodiment, rails 28 are only several inches in height above deck 18. Rails 28 need not be formed of any particular material or have any particular shape. In one example, rails 28 may be formed of standard 2 inch angle iron while in another embodiment, rails 28 have a height of no more than 5 inches. In yet another embodiment, rails 28 have a height of no more than 12 inches. In another example, rails 28 may be formed of rubber bumpers. Likewise, rails 28 need not be continuous, but may be intermittent so long as they create a “seat” for receipt of a storage basket 22. Thus, in one preferred embodiment, rails 28 may be positioned only at the corners of a cell 30, such as is illustrated at 32, or only along a portion of the sides of cell 30. In any event, the height of rails 28 need only be of sufficient height to ensure that a storage basket 22 securely seats within a cell 30 thereby preventing the storage basket from shifting or tipping.
By seating a plurality of storage baskets 22 adjacent one another along an x-axis row 29 or a y-axis row 31, a wall 34 of storage baskets 22 can be formed. Because each storage basket 22 that comprises wall 34 is securely seated within their respective cells 30 and because each storage basket 22 desirably has a low center of gravity, each wall 34 is relatively stable. For purposes of the description, wall 34 may in some cases only comprise a single storage basket so long as it provides the intended function as more specifically described below.
An external containment wall 36 is defined around the perimeter of grid 26. In the preferred embodiment, external containment wall 36 has a greater height than rails 28. External containment wall 36 is likewise aligned along x-axis 25 and y-axis 27 to be parallel and perpendicular with walls 34, as the case may be, thereby forming open travel paths 38 for movement of storage baskets 22. The height of containment wall 36 is preferably commensurate with the height of walls 34. In one preferred embodiment, the height of external containment wall 36 is three feet.
An overhead gantry or bridge crane 40 is positioned on deck 18 to operate along the x-axis 25 and y-axis 27 over the top of the grid 26 to move individual storage baskets 22 along a travel path 38 between stations 21 and storage locations within grid 26. Gantry 40 is capable of moving baskets 22 along both x-axis rows 29 and y-axis rows 31. Furthermore, gantry 40 is itself only a sufficient height above deck 18 necessary clear the walls 34 formed by storage baskets 22. In one preferred embodiment, gantry 40 is only eleven feet above deck 18. Because gantry 40 is disposed to move baskets 22 along travel paths 38, gantry 40 need not be capable of lifting a basket 22 above walls 34. Rather, gantry 40 need only lift a basket 22 a sufficient height above deck 18 to clear the height of rails 28. Thus, in one preferred embodiment gantry 40 need only lift a basket 22 approximately three inches above deck 18 in order to move basket 22 along a travel path 38. As a basket 22 is moved through grid 26 along a travel path 38, uncontrolled swinging of basket 22 is inhibited by external containment wall 36 and “internal” wall 34. Furthermore, since basket 22 need only be lifted inches above deck 18 in order to be moved through grid 26, swinging movement of basket 22 is also prevented by deck 18 since the width and length of basket 22 are much greater than the height of basket 22 above deck 18.
In the preferred embodiment, gantry 40 includes a gantry head (not shown) capable of rotating each OBS unit 22 so that it will be properly oriented in basket 22 to permit charging, data extraction, etc.
Those skilled in the art will understand that desired travel paths 38 can be defined within grid 26 by placement of baskets 22 within specific cells 30. Such travel paths 38 can be defined along either an x-axis row 29, a y-axis row 31 or both. Baskets 22 can be moved around within grid 26 as necessary to create additional travel paths 38 or to access different baskets 22. Furthermore, travel paths 38 can be formed internally within grid 26 between opposing walls 34, such as is illustrated at 35, or adjacent the perimeter of grid 26 between external wall 36 and internally formed wall 34, as is illustrated at 37. In this regard, as indicated above, an internally formed wall 34 can be formed of a single basket 22, such as is shown at 39, so long as the wall provides the constraint functions described above.
In another embodiment of the invention, poles or similar structures 42 may be utilized to form a part of travel path 38 for movement of individual storage baskets 22 when the desired travel path is not bounded by external containment walls 36 or “internal” walls 34. In the illustrated embodiment of
Those skilled in the art will understand that storage area 24 is scalable to meet the particular OBS unit storage needs and space limitations of a vessel. In
In one preferred embodiment parallel and perpendicular rails 28 that form grid 26 are configured to have the dimensions of a standard 8′×20′×8′ shipping container so that each 8′ section of storage area 24, as well as any baskets 22 and OBS units 22 stored therein, can be easily transported utilizing standard container ships, and quickly assembled on the deck of any standard seismic vessel. To further facilitate transport to a staging or assembly location, baskets 22 may also be stackable. Likewise, the stations 21 and other components can be modular, preferably with dimensions of standard shipping containers, to facilitate assembly on deck 18.
The travel paths formed by the internal walls, the external walls and the poles permit a storage basket to be moved much more safely between storage locations within a storage grid and various stations on the vessel's deck while maintaining maximum control over movement of the storage basket. This is particularly desirable in the case of onerous weather conditions. The poles, external containment wall and “internal” walls formed by rows of storage baskets constrain swinging of baskets, even in conditions where the surface vessel itself may be moving significantly. Furthermore, since the “internal” walls of the grid can be reconfigured as desired in order to free up a particular storage basket, the system is very flexible to meet the needs of a desired operation. Various stations can be integrated with the system, such as stations for OBS unit charging, data extraction and maintenance, as well as stations where the individual OBS units can be moved between the storage basket and a deployment/retrieval vehicle or mechanism.
Number | Name | Date | Kind |
---|---|---|---|
2440306 | Smith | Apr 1948 | A |
2963310 | Abolins | Dec 1960 | A |
3359752 | Westling et al. | Dec 1967 | A |
3583350 | Goldman | Jun 1971 | A |
3950803 | Reynolds et al. | Apr 1976 | A |
4270598 | Britton | Jun 1981 | A |
4655153 | Bel | Apr 1987 | A |
4716848 | Smith et al. | Jan 1988 | A |
6666635 | Holt et al. | Dec 2003 | B2 |
7210556 | Bath et al | May 2007 | B2 |
7310287 | Ray et al. | Dec 2007 | B2 |
20030218937 | Berg et al. | Nov 2003 | A1 |
20060120216 | Ray et al. | Jun 2006 | A1 |
Number | Date | Country | |
---|---|---|---|
20060243189 A1 | Nov 2006 | US |