The present invention relates to means for disabling small water craft, such as are often used for hijacking or terrorist operations.
Small watercraft can pose a hazard to commercial shipping and even naval ships. Regarding the former, Somali pirates have disrupted commercial shipping in the Gulf of Aden and even into the Indian Ocean. In 2008, these pirates collected in excess of $150 M in ransom from hijacked ship owners. The pirates use small craft to assault the ship; grappling hooks are used to secure lines, board the ship and seize control. Since modern merchant ships are highly automated, there are typically only small crews for onboard for defense. This enables pirates to easily overpower the crew and operate the ship after hijacking.
When maneuvering in restricted conditions, moored, or at anchor, naval vessels are particularly vulnerable to attack from a group of small, fast boats. Due to their size, speed, and maneuverability, these small boats can attack and then run and hide from larger navy vessels. To make matters worse, hostiles will often be operating in their own waters where they will typically enjoy a significant numerical advantage and superior knowledge of the waterways. This type of attack, which is referred to as a “small-boat-swarm,” is the tactic of choice for terrorists.
There are no truly cost-effective options for addressing the piracy issue. The naval response to small-boat-swarm has been to deploy similarly-sized, stealthy, fast, heavily-armed craft. An appropriately outfitted Zodiac-type raft has been used for this service. But even highly-trained navy personnel have a limited capability to withstand the repeated shock to their bodies that occurs when traveling in such craft at high speed in moderately high sea states.
The present invention provides a cost effective and non-lethal way to disable a small boat, such as used by pirates or terrorists. In accordance with the illustrative embodiment of the invention, a system for disabling a small boat comprises (1) two hulls, (2) a propulsion subsystem, (3) a homing, guidance, and control subsystem, (4) a depth-control subsystem, and (5) an entanglement device, typically comprising a long, stranded material that is neutrally or positively buoyant, suitably strong to be deployed by the moving hulls and not capable of being shredded by a prop.
The system, which is relatively small, is maintained aboard a commercial or naval vessel. If a small craft is detected by ships' crew or on-board sensors, and if it is determined or likely that operators of the small craft have malicious intent, the system is deployed in the water.
The homing, guidance, and control subsystem acquires the target and causes the propulsion subsystem to move the system toward the small craft. As the system nears the target, the entanglement device is deployed. The entanglement device is deployed by increasing the distance between the two hulls, thereby causing the net, etc., to spread out near the surface of the water.
The intent of the entanglement device is, as its name suggests, to become entangled with the target craft. As previously noted, the entanglement device is a neutrally or positively buoyant, long, stranded material. In some embodiments, the entanglement device is a neutrally or positively buoyant net of monofilament construction and includes a plurality of strands of fibrous material that extend from net. If the small craft is propeller driven, the net or strands become entangled with the prop or other protruding features of the craft. If the small craft is a jet boat, the strands of fibrous material will be ingested into the jet intakes. In either case, the small craft will be incapacitated and rendered motionless in the water.
Assuming that the small boat is disabled at an acceptable standoff distance (several hundred meters, etc.) from the ship, its mission will be frustrated. For example, in the case of attempted piracy, the pirates will be prevented from boarding and there will be ample time for the commercial ship to escape and radio for help. Or, if the encounter is with a naval vessel, the small boat will not be able to approach the hull to place explosives or perpetuate other acts of sabotage. And the naval vessel can respond as appropriate.
Since the system is non-lethal, it presents decreased safety risks for the crew. Furthermore, if the system is deployed against what turns out to be a non-hostile target, there will be no loss of life and any potential liability will be significantly reduced. The system is intended to be disposable, so a relatively minimal level of sophistication in terms of tracking, guidance, and control systems is desirable.
In some embodiments, the two hulls are small, unmanned underwater vehicles (“UUVs”). In such embodiments, the propulsion subsystem, homing, guidance, and control subsystem, depth-control subsystem (typically a ballasting system), and propulsion subsystem will be onboard each UUV.
In some other embodiments, one or both of the hulls is powered (i.e., propulsion hulls), but they are not autonomous in the sense of a UUV. In such embodiments, the two hulls are typically each coupled via movable linkages to a third hull, which can house the homing, guidance, and control subsystem. These embodiments incorporate a mechanism for reconfiguring the linkages, which changes the separation distance between the hulls to deploy the entanglement device.
In still further embodiments, the hulls are not powered; rather they are attached to a third hull that incorporates a propulsion subsystem and a homing, guidance, and control subsystem. The hulls typically include the depth-control subsystem (e.g., a ballasting system, etc.).
The illustrative embodiment of a system for disabling small watercraft comprises:
two hulls, wherein the separation distance between the hulls can be changed;
a way to propel and guide the hulls through water to a target;
an ability to float or submerge;
an entanglement device for disabling the target.
This system can be implemented in a variety of ways, a few of which are described herein and depicted in the accompanying drawings.
UUVs 102A and 102B can be any one of a number of available UUVs, including, without limitation, Mk 39 EMATT, SUBMATT, as available from Lockheed Martin, or other suitable UUVs. Each UUV includes homing, guidance, and control subsystem 104, depth-control subsystem 105, and propulsion subsystem 106.
In some embodiments, homing, guidance, control subsystem 104 comprises passive and/or active sensors for acquiring the small craft and a processor running software capable of estimating a trajectory of the small craft and/or an intercept trajectory. Having acquired the position of the small craft, the guidance system issues commands, for example, to the propulsion systems of UUV 102A and 102B to propel system 100 toward the target. It will be appreciated by those skilled in the art that any one of a number of approaches to acoustic tracking, guidance, and control can be used for homing, guidance, and control system 104. It is within the capabilities of those skilled in the art to design and implement such systems.
In the illustrative embodiment, depth-control subsystem 105 is a conventional ballasting system, well known to those skilled in the art. Propulsion subsystem 106 comprises an electrically-driven propulsor or water jet, or other thrust-generating systems suitable for propelling UUVs, as a function of their size.
In accordance with the illustrative embodiment, entanglement device 108 comprises net 110 (e.g., monofilament, etc.) having fibrous “streamers” 111 extending therefrom. In some embodiments, streamers 111 comprise a plurality of elongated strands of fibrous material, each of which strands has a length that is typically in the range of about 1 to 4 meters. Entanglement device 108 need not be a net, per se; it can take any form that is suitable for disabling the propulsion system (e.g. entangling the propellers or other external features, fouling the intakes of a jet-propelled craft, etc.) of a target.
Operation of a system for disabling a small craft, such as system 100, is now described in conjunction with
In response, the crew of the commercial vessel deploys system 100 into the water, as depicted in
Once in the water, acoustic sensors associated with system 100 acquire craft 220 and develop trajectory estimates and an intercept solution. See also,
System 100 then transits toward target 220 in accordance with trajectory/intercept estimates. See also,
As system 100 approaches target 220, it surfaces. After surfacing, or just prior to surfacing, and in response to a command from a human operator or in accordance with system programming, UUVs 102A and 102B increase their separation distance, thereby deploying entanglement device 108 as depicted in
With entanglement device 108 deployed (e.g., net with streamers, etc.), system 100 engages target 220, as depicted in
In some further embodiments, more than one instance of system 100 is used. The use of a relatively larger number of these systems increases the potential reach of entangling device 108 and, of course, is required when the attacking force includes plural small watercraft.
Referring now to
System 300 comprises hulls 302A and 302B, secondary hull 326, linkages 312A and 312B, and entanglement device 108, interrelated as shown.
With particular reference to
In the embodiment of system 300 depicted in
Linkages 312A and 312B are capable of reconfiguring to change the separation distance between hulls 302A and 302B by allowing the linkage members to partially rotate relative to one another. Compare, for example,
System 300 includes a mechanism or arrangement for reconfiguring linkages 312A and 312B. In the embodiment depicted in
In conjunction with the present disclosure, those skilled in the art will be able to design and incorporate any one of a variety of mechanisms suitable for accomplishing the above-described functionality (i.e., reconfiguring linkages 312A and 312B). It is notable that for most contemplated uses, it is not necessary for linkages 312A and 312B to be able to autonomously return to their stowed after entanglement device 108 is deployed. After successful deployment and immobilization of a target, system 300 can be reset manually after recovery, to the extent recovery is desired. That is, with its relatively low cost, system 300 can be considered to be disposable.
Referring now to
System 400 comprises hulls 402A and 402B, secondary hull 426, two sets each of linkages 412A and 412B, and entanglement device 108, interrelated as shown.
Linkages 412A and 412B function in the manner of linkages 312A and 312B, previously described. Hulls 402A and 402B depth-control subsystem 405 (e.g., ballasting system, etc.). Homing, guidance, and control subsystem 104, and propulsion subsystem 106 are disposed in secondary hull 426.
It is to be understood that the disclosure teaches just one example of the illustrative embodiment and that many variations of the invention can easily be devised by those skilled in the art after reading this disclosure and that the scope of the present invention is to be determined by the following claims.
This case claims priority of the following U.S. Provisional Patent Applications Ser. No. 61/173,267 filed Apr. 28, 2009 and 61/174,249 filed Apr. 30, 2009. Both of these applications are incorporated by reference herein.
Number | Date | Country | |
---|---|---|---|
61173267 | Apr 2009 | US | |
61174249 | Apr 2009 | US |