The present invention relates generally to subsea excavation and mining.
Seabed excavation using equipment deployed from surface support vessels is well known. This general technique is routinely used by the marine dredging industry and subsea mining industry. Prior art in these fields is discussed below.
The dredging industry uses a range of excavation tools. The tools are generally suspended from surface support vessels by means of lowering equipment, such as winches or hydraulic elevators, which are located on the deck of the surface support vessel. There are many different kinds of excavation tools and
The majority of marine dredging activity takes place in shallow water coastal waters. In deep water conditions (over 300 m water depth say) control over the excavation trajectory using these prior art techniques becomes increasingly difficult due to the practical limitations of distance between the surface support vessel and excavation tool on the seabed. In ultra-deep water conditions (over 1,000 m water depth say) efficient control using these techniques is likely to be almost impossible.
The subsea mining industry has developed alternative methods compared to the marine dredging industry. One of the drivers for new methods has been the requirement of this industry to operate in open water further from the coastline, and in rather greater water depths compared to the marine dredging industry. Some of the prior art in this field is discussed below.
Seabed drilling systems are used from drill ships by De Beers for diamond mining in South Africa and Namibia. These drills use the “reverse circulation” technique in which the excavated seabed material is drilled with a very large diameter drill bit and sucked up through the riser pipe 52. Apart from that aspect, the drilling technique is relatively conventional with a drill pipe suspended vertically from a deck-mounted derrick tower 39 and hoist 51.
One of the major drawbacks of this technique is that drilling trajectory is purely vertical and there is no ability to steer the drill bit in a horizontal direction. As such the drill bit must be continually inserted, withdrawn following drilling, and then re-positioned on the seabed so the excavation takes place in a discrete and inefficient “cookie cutter” pattern. The circular nature of the drill bit makes it difficult to join the excavated holes together to make a contiguous excavation.
Another disadvantage is the difficulty in accurately controlling the position of the drill bit. If the mining operation is to be done efficiently, the location of the drill hole must be accurately controlled. Such accuracy can be difficult to achieve, particularly in deep water and in locations where the terrain is rugged (such as in most seabed massive sulphide ore deposits).
A further disadvantage in deep water is due to the fact that the power transfer to the drill bit is mechanically provided by the drill string. The downward force on the drill bit must be provided by the weight of the drill string, and this weight must be accurately controlled. Furthermore, the high torque requirements for the large diameter drill bit must also be provided through the drill string.
As an improvement over the drill ship method, De Beers have also developed a seabed crawler vehicle technique. This is illustrated in
An important distinction between different seabed crawlers is the number of degrees of freedom between the crawler vehicle 53 and the excavation tool 54. If the number of degrees of freedom is low, then the crawler vehicle 53 can make continuous horizontal cuts as it moves about the terrain. If the machine has enough degrees of freedom, it can sit in one place and make 3-dimensional cuts in its local vicinity. However, because a seabed crawler 53 must provide counter-balancing forces, it will be much heavier than a machine of similar production rate and have fewer degrees of freedom.
The seabed crawler vehicle technique has its own disadvantages. One of the key disadvantages being that the surface support vessel 18 is connected to the seabed crawler vehicle 53 by means of a flexible pipe 30 as opposed to a fixed steel pipe. Such flexible pipes are specialist products and extremely expensive to manufacture. Furthermore it is often difficult to adjust the length of this flexible pipe because such pipes are generally manufactured in fixed lengths. This can make it correspondingly more difficult to adjust the seabed crawler technique to account for varying water depths, when compared to techniques which use fixed steel pipes which can be routinely and cheaply made up as required in conventional multi-joint lengths.
Another disadvantage of the seabed crawler vehicle is that it relies on competent and flat seabed terrain for stability during steering. There are notorious examples of severe instability occurring on unstable and sloping seabeds, which has caused the failure of entire mining projects. For example, the terrain around the richest type of mining deposits, seabed massive sulphides, is notoriously rugged.
The third disadvantage of the seabed crawler is that, in order to achieve high production rates, the crawler becomes very large. This is due to the relationship between production rate and excavation tool size, and the further relationship between excavation tool size and crawler size. Because the crawler must provide its own counter-balancing forces, only a fraction of the weight of the crawler can be applied to the excavation tool.
A further example of a method from the subsea mining industry is the use of a vertically-suspended trench cutter type excavator which is hung from a surface support vessel.
An advantage of the vertically-suspended trench cutter compared to the drill ship technique described above is that the section excavated in each cut is rectangular in plan (rather than circular as provided by the drill) and a continuous excavation plan is more efficiently formed. Like the seabed crawler, the trench cutter decouples the power transfer from the surface support vessel and provides it locally. A particular advantage is that the machine is very weight-efficient. The weight of the entire machine stands on the cutters, so the machine can be made much lighter than a seabed crawler with the same production rate. However the key disadvantage is that it is a one-dimensional excavator; there is no included means for creating a horizontal excavation trajectory.
Another technique that has been used is steering the drill bit 61 in a horizontal trajectory by means of tugger lines 62 from the deck of the surface support vessel 18. This technique is shown in Kuntz, U.S. Pat. No. 3,763,580 “Apparatus for Dredging in Deep Ocean,” see
However, it is noted that the use of the tugger lines deployed from the deck of the surface support vessel will have practical limitations and will represent a disadvantage in ultra-deep water as described above in relation to techniques used by the marine dredging industry.
Yu U.S. Pat. No. 7,690,135 “Deep Sea Mining Riser and Lift System,” describes a variation on the seabed crawler vehicle technique that replaces the flexible pipe 30 for lifting the slurry with rigid pipe 38 for the majority of length connecting the seabed crawler vehicle 53 to the surface support vessel 18. This patent describes that the use of flexible pipe 30 is now limited to a far shorter fixed length “jumper” section connecting between the crawler vehicle 53 and bottom of the rigid pipe 38. See
It is an object of the present invention to provide methods and systems for efficiently excavating or mining the seabed. The excavation process requires positioning and stabilizing the excavator relative to the seabed and exerting force between the excavator and the soil, rock, ore, or other material to be excavated. Examples of the present invention address this process by exerting force between a subsea anchor point and an excavator using a subsea actuator. In some examples the subsea actuator is attached to an anchor point on the seabed and the excavator directly. In other examples, a guide frame is anchored to the seabed to provide anchor points fixed relative to the seabed and the subsea actuators are attached to the guide frame and the excavator. In further examples, the subsea actuators can be attached to the excavator through a carrier frame or other excavator guides rather than directly to the excavator.
According to a first example of the invention, a subsea excavation apparatus is provided. The apparatus comprises: an excavator; a first anchor point in a first fixed location relative to the seabed; a first subsea actuator attached to the excavator and the first anchor point for converting power to mechanical force between the first anchor point and the excavator; wherein the subsea actuator exerts force in response to actuator control signals. In some systems, the first subsea actuator is positioned and arranged to exert force primarily horizontally. In some other systems, the first subsea actuator is positioned and arranged to exert force primarily vertically. In many systems, the first subsea actuator is for converting electrical power to mechanical force. In some other systems, the first subsea actuator is for converting hydraulic power to mechanical force. In some systems, the first subsea actuator comprises a unidirectional actuator. In some other systems, the first subsea actuator comprises a bidirectional actuator. In many systems, the first subsea actuator is responsive to actuator control signals to manage the location of the excavator on an excavation face. In many systems, the excavator is responsive to excavator control signals. In some systems, excavator control signals and actuator control signals are provided interdependently to manage excavation location and rate.
According to a further example of the invention, a subsea excavation apparatus is provided that further comprises: a second anchor point in a second fixed location relative to the seabed; a third anchor point in a third fixed location relative to the seabed; a second subsea actuator attached to the excavator and the second anchor point for converting power to mechanical force between the second anchor point and the excavator; a third subsea actuator attached to the excavator and the third anchor point for converting power to mechanical force between the third anchor point and the excavator; wherein the second and third subsea actuator exert force in response to actuator control signals. In some such example systems, the first, second, and third subsea actuators are responsive to actuator control signals to manage the location of the excavator on an excavation face in three dimensions. In some examples, the actuator control signals are used to manage the orientation of the excavator on an excavation face. In some examples, the actuator control signals are used to manage the location and orientation of the excavator on an excavation face.
According to another example of the invention, a method for controlling a subsea excavator is provided. The method comprises: maintaining a plurality of anchor points at a fixed locations relative to the seabed; providing power to a plurality of subsea actuators; converting the power to a mechanical force with each subsea actuator; applying the mechanical forces between the subsea excavator and the plurality of anchor points; providing actuator control signals to the plurality of subsea actuators. In some such methods, the actuator control signals control the forces and moments on the excavator in three dimensions. In some example methods, the actuator control signals control the forces and moments exerted by the plurality of subsea actuators. In some such methods, the actuator control signals control the movement of the plurality of subsea actuators. In many example methods, the actuator control signals are used to manage the location of the excavator on an excavation face. In many example methods, the power is provided by a support vessel. In some example methods, the plurality of subsea actuators comprises unidirectional actuators. In other example methods, the plurality of subsea actuators comprises bidirectional actuators.
In a further example of the invention, a method for controlling a subsea excavator is provided that further comprises providing excavator control signals to the excavator.
Examples embodiments of the present invention overcome the disadvantages in the prior art as described above and consequently provide more efficient systems and methods for Seabed Excavation particularly in ultra-deep water conditions. The example embodiments provide economic advantages compared to previous techniques.
These example embodiments can utilize existing, weight-efficient excavating and cutting technology, for example the Bauer trench cutter (
These example embodiments can also use a wide variety of seabed anchor technologies to provide anchor points including: gravity anchors, drilled and grouted piles, suction piles, drag embedment anchors, torpedo anchors, and screw anchors.
In at least one example embodiment of the invention, a subsea excavation apparatus is provided that includes an excavator that is positioned by subsea actuators in response to actuator control signals. The actuator control signals can command either or both a specific force or position from the actuator. Each subsea actuator converts power into mechanical force and is mounted between an anchor point in a fixed location relative to the seabed and the excavator. In various example embodiments, the subsea actuator receives either electric or hydraulic power from a surface support vessel. By providing a subsea actuator that is attached to an anchor point, these examples increase efficiency of deep sea operation and require less costly surface support vessels and/or platforms than previous methods. Because the excavator is positioned relative to an anchor point that is fixed relative to the seabed, costly support vessel station keeping and motion compensation systems are not required. Additionally, the necessity for long mechanical linkages between the surface and seabed are replaced with more efficient means of providing power to the seabed, such as electrical or hydraulic transmission.
In further examples, the actuator control signals to multiple subsea actuators can manage excavation rate and location by controlling the position of the excavator relative to the seabed in three dimensions and controlling the force exerted on the excavation face by the excavator.
In further example embodiments, the excavator may be responsive to excavator control signals to control the rate of excavation and/or extraction of excavated materials.
In further example embodiments, the actuator and excavator control signals are adjusted in concert to control the rate of extraction. The excavator and actuator control signals may operate in a feedback loop where each is adjusted in response to the other, or in response to feedback from either the excavator or actuators. For example, if the torque requirements on THE excavator's rotating cutter start to exceed its capabilities, the excavation rate could be reduced by either reducing the force exerted on the excavator by the actuators toward the excavation face and thereby reducing the effective depth of the cut, or by reducing the force exerted on the excavator by the actuators along the excavation face thereby reducing the advance rate of the excavator.
In further example embodiments, the system can contain three or more subsea actuators to exert force on the excavator in three dimensions.
In other example embodiments, a method for controlling a subsea excavator is provided where anchor points are maintained in fixed locations relative to the seabed, power is provided to a subsea actuator, the subsea actuator exerts force between an anchor point and the excavator in response to actuator control signals. This method can be applied with the example system embodiments described. By providing a subsea anchor point and subsea actuator, these examples increase efficiency of deep sea operation and require less costly surface support vessels and/or platforms than previous methods. Costly support vessel station keeping and motion compensation systems are not required because the excavator is positioned relative to the seabed rather and a surface support vessel or platform. Additionally, the necessity for long mechanical linkages between the surface and seabed can be replaced with more efficient means of providing power to the seabed, such as electrical or hydraulic transmission.
One example embodiment is a method to utilize existing excavators to efficiently mine in the deep sea. This involves the use of remotely controlled equipment, coupled with the weight of the machine, to accurately control the excavation trajectory of the machine, in three dimensions, over large areas.
One example embodiment uses subsea winches as actuators, flexible and rigid pipe (for lifting of an excavated slurry), a controllable lowering winch for the excavator and vertical actuator, Remotely Operated Vehicles, and possibly a submerged, suspended guide frame to facilitate control of the excavator.
As mentioned above, the means for guiding subsea excavating equipment has traditionally been one of the following means: 1) maneuvering the support vessel 18 by means of anchor lines or thrusters to control a suspended pipe or cable (see e.g.
Examples of the present invention introduce the use of subsea actuators (such as winches and hydraulic cylinders), ROVs, cable supported excavators and seabed anchors to allow for efficient extraction of minerals from the seabed. This approach has not been used previously for a variety of reasons. First, it has been stated that solutions involving a winch anchored to a fixed point as in
This objection is overcome in examples of the present invention by allowing the use of a fixed point relative to the seabed as the anchoring point in combination with a subsea actuator. In some examples this anchor point is a gravity anchor, a drilled and grouted pile, a driven pile, a suction pile, a drag embedment, a torpedo anchor, a screw anchor, or a subsea drilled anchor.
Placing a fixed anchor point on the seabed in the deep sea is constrained by the magnitude of the lateral forces required to cut the rock. In some examples of the invention, this objection is overcome by minimizing these forces through the use of an excavator which provides the primary cutting forces by its own weight. Two excavating scenarios are envisioned. In one case the excavator, similar to
Examples of the invention may be used for either vertical excavation (similar to trench cutting), or lateral excavation (similar to strip mining).
According to some examples embodiments, it is possible to completely excavate a deposit by vertical cutting alone. A vertical cutting machine type excavator can excavate a trench in one direction using the weight of the excavator alone to stabilize the cut. The weight of the device can be sufficient to provide cutting forces without any external forces being applied. Inclination of the cutter is arrested by bearing pads 2 on the outside of the cutter frame 1 which bear against the walls of the trench. Mining an open pit with such a device is more complicated. Various hole-patterns for an open pit process using a trench cutter are possible. The cutter may be rotary (creating a circular hole) or rectangular (creating a rectangular hole). As the pit is expanded, the cuts are made without the aid of trench walls for support. Lateral reaction forces 44 are provided to maintain the stability of the excavator 16, shown in
In the example embodiment shown in
In the example embodiment shown in
The example embodiment shown in
The example embodiment shown in
In the example embodiment shown in
The above examples pertain primarily to vertical excavation which may be the most efficient available for irregular sea beds, pillars and very narrow deep deposits. As noted those examples require guidance of the cutter during pit expansion, which may be difficult with a cable guided system. The following examples illustrate how the same basic cutting machine may be extended for lateral cutting similar to surface mining using cable and winch guidance.
This principle of static equilibrium is well known in engineering mechanics. The values in this example are only for illustration and specific values will vary from application to application due to different cutter head weights and dimensions, and different rock cutting forces. In order to maintain equilibrium for different cutting forces the external applied loads will need adjustment.
Another embodiment using the submerged frame is shown in
Note that the cutter is not restricted to making passes of equal depth, whether it is dragged by anchor points attached to a guide frame or to the seabed—the depth of cut can be varied to “sculpt” the seabed, e.g. to excavate a rounded pit to follow an orebody. Furthermore, the heading orientation of the machine can be changed, e.g. using cables as shown in
Also note that, if a frame as shown in
Calculations have been performed for the performance of the system shown in
Cutting depth: 2 m Cutting width: 0.84 m Rock production: 0.4 cu m/min Forward Speed: 0.25 m/min
Assumed track length: 200 m Cycle time (per track): 800 m (13.3 hours)
The track length could be shortened or extended as appropriate for the topography. Many tracks should be possible to achieve with a single drag line/anchor placement, provided lateral guidance is provided.
Experience with trench cutters would suggest about a 16 hour cycle on changing out of teeth. This might argue for two units on separate hoist lines with one ready to commence a second pass when the first machine completes a pass and is retrieved.
The foregoing description is presented for purposes of illustration and description, and is not intended to limit the invention to the forms disclosed herein. Consequently, variations and modifications commensurate with the above disclosures and the disclosure of the relevant art are within the spirit of the invention. Such variations will readily suggest themselves to those skilled in the relevant art. Further, the examples described are also intended to explain the best mode for carrying out the invention, and to enable others skilled in the art to utilize the invention and such or other embodiments and with various modifications required by the particular applications or uses of the invention. It is intended that the appended claims be construed to include alternative embodiments to the extent that is permitted by prior art.
This application is a continuation of U.S. application Ser. No. 13/816,867, filed Feb. 13, 2013, which is the national phase application of PCT/US11/47599, filed Aug. 12, 2011, which claims the benefit of U.S. Provisional App. No. 61/373,627, Aug. 13, 2010.
Number | Date | Country | |
---|---|---|---|
61373627 | Aug 2010 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13816867 | Feb 2013 | US |
Child | 14560443 | US |