1. Field of the Invention
The present invention relates generally to the field of explosive ordinance disposal (EOD) and more particularly to EOD using robotic devices with various disposal attachments thereon.
2. Description of the Related Art
There are many situations in which police, military personnel or others require the ability to dispose of or render safe an explosive device, e.g., landmines, improvised explosive devices (IEDs), CBRN (chemical/biological/radiological/nuclear) devices, etc. while minimizing risk to themselves and others. Remotely operated robots have been developed to investigate potential explosive devices and in some cases are used to disable the devices or to detonate in a controlled manner. Examples of such robots include the PackBot series available from iRobot and the Talon series available from Foster Miller.
The iRobot PackBot and the Foster Miller Talon may be used to disrupt IEDs, military ordnance, land mines, etc. Both the PackBot and the Talon utilize an extendible arm and may include a gripper for picking up and placing different sized objects, including disruptors. Disruptors are devices that contain, e.g., gunpowder, water or other disruptive material. The disruptors may be in the shape of a plastic water bottle, briefcase or the like. The disruptors are placed close to, for example, an IED, in order to detonate or disable the IED. There are numerous accessories available for the PackBot in order to facilitate disruption including, for example, a flipper tool bar kit and a main ordnance lift kit which attach to the PackBot and uses flippers to move implements up and down.
The PackBot and Talon robots may also work with disruptor guns which fire projectiles, e.g., water, clay, rubber bullets, and the like at IEDs in order to disrupt the trigger mechanism and or facilitate controlled detonation. Additional accessories have been developed by other companies, e.g., Proparms Ltd. and Ideal Products, to work with the PackBot, Talon and other robots. Ideal Products offers a trade named PAN Disruptor™ wherein PAN stands for Percussion Actuated Non-electric. The PAN Disruptor™ is a tool that is connected to the arm of a robot to safely dismember and disarm explosive packages with unknown content by firing water, clay or lead shot to take apart packages with unknown content.
A major obstacle to successfully disabling explosives is the risk posed to EOD personnel. The ability to remotely disable is desired. Further, current configurations for placing disruptors are unreliable as the arms on the PackBot and Talon robots are unable to carry the weight of and sustain the loading required by the disruptors.
The embodiments of the present invention facilitate disabling explosives while minimizing risk to EOD personnel. In a first exemplary embodiment, a system for placing a gun barrel within firing distance of a target is described. The system comprises: a remote controlled vehicle including a remotely controllable arm; a first component attached to the vehicle, the first component including parallel vertical tracks; and a second component including first and second sets of rollers for rolling the second component along the parallel vertical tracks, the second component further including a gun barrel positioned approximately perpendicular to the parallel vertical tracks.
In a second exemplary embodiment, an alternative system for placing a gun barrel within firing distance of a target is described. The system comprises a remote controlled vehicle including a remotely controllable arm and a component attached to the vehicle including a clamp for holding the gun barrel, support means connected to the clamp and including at least one shock absorber, and attachment means for attaching the component to the vehicle.
In a third exemplary embodiment, a system for placing a disruptive device near a target is described. The system comprises: a remote controlled vehicle including a remotely controllable arm; a first subsystem; and a second subsystem including a holder for holding the disruptive device and a release mechanism for releasing the disruptive device near the target. The first subsystem includes a movable arm, a hook, a retaining pin, and a lowering mechanism. The release mechanism releases the disruptive device from the holder when the remotely controllable arm causes the movable arm to unhook the hook from the retaining pin which causes the lowering mechanism to drop the second subsystem which triggers the release mechanism.
In a fourth exemplary embodiment, an alternative system for placing a disruptive device near a target is described. The system comprises a remote controlled vehicle including a remotely controllable lowering mechanism and a subsystem including a holder for holding the disruptive device and a release mechanism for releasing the disruptive device near the target. The release mechanism includes a cam, at least one buckle, at least one strap, and a foot actuator. The release mechanism releases the disruptive device from the holder when the lowering mechanism causes the subsystem to drop and the foot actuator hits the ground causing the cam to release the buckle which holds the strap, thus releasing the disruptive device from the holder.
In a fifth exemplary embodiment, an alternative system for placing a disruptive device near a target is described. The system comprises a remote controlled vehicle including a remotely controllable arm and a subsystem that includes a movable arm, a hook, a retaining pin, a lowering mechanism, a pivot component; and a holder for holding the disruptive device. The disruptive device slides off of the holder when the remotely controllable arm causes the movable arm to unhook the hook from the retaining pin which causes the lowering mechanism to cause the holder to pivot around the pivot component, thus lowering an edge of the holder and causing the disruptive device to slide off of the holder.
The preferred embodiments of the present invention are illustrated by way of example and not limited to the following figures:
a) to 1(c) illustrate an embodiment of the present invention including a disruptor assembly for use with a first prior art robot;
a) to 2(c) illustrate an embodiment of the present invention including a disruptor assembly with trailer for use with a first prior art robot;
a) to 3(c) illustrate an embodiment of the present invention including a disruptor assembly for use with a second prior art robot;
a) to 4(d) illustrate an embodiment of the present invention including a container placement assembly for use with a first prior art robot;
a) to 5(c) illustrate an embodiment of the present invention including a container placement assembly for use with a second prior art robot;
a) to 6(e) illustrate an embodiment of the present invention including a second container placement assembly for use with a first prior art robot; and
a) and 1(b) illustrate a tool for attaching a pan disruptor to Foster Miller's Talon robot. A pan disruptor is essentially a gun that can fire several different types of projectiles, e.g., water, bullets, clay, etc. depending on the need. The Foster Miller Talon may be fitted with the pan disruptor described in the preferred embodiment either directly or via a trailer skid assembly as described herein with respect to
Referring to
Referring to
c) illustrates the combination of components 10 and 50 mounted on Talon robot 75.
The first component 10 is attached directly to the Talon robot 75 at multiple connection points via the pan mount outer tool clip 28 and bottom tool clamp 30 and via rear axle braces 22 and support pins 23 as shown in
Further to
Referring to
With respect to this second exemplary embodiment, the location, e.g., elevation, of the disruptor gun 52 is controlled in the same manner as described above with respect to the first exemplary embodiment (cables, etc. not shown).
One skilled in the art recognizes that the there are numerous nuts, bolts, screws and the like which are used to attach the components described herein. Accordingly, these nuts, bolts, screws, etc. are not discussed individually. While the pan disruptor configurations shown with respect to
a) to 3(c) illustrate a third embodiment of the present invention that includes a pan disruptor configuration for use with the iRobot PackBot robots such as the EOD and MTRS versions. More particularly,
b) illustrates an unexploded view of the pan disruptor configuration for use with the iRobot PackBot robot.
c) illustrates the combined system 250 including pan disruptor assembly 200 attached to an iRobot PackBot robot 240.
A fourth embodiment of the present invention is directed to a system for remotely placing a container, e.g., containing water and/or explosives. Water is an effective tool for disrupting the circuitry and fuses for IEDs. Accordingly, the ability to place a container of water near an IED so that it can be exploded in order to disrupt circuitry, fuses and the like is needed. In particular, a system that allows for the remote placement of the water container in order to shield human operators is preferred. Referring to
When hook 312 comes off of retaining pin 314, the parallelogram assembly 327 moves so as to lower holding block 332 which is attached to the parallelogram assembly 327 via front rack support 330. When holding block 332 is dropped, foot actuator 342 hits the ground and threaded coupler 338 attached to the foot actuator 342 through threaded rod 340 is pushed up which causes a cam 334 to pull a cable (not shown) actuating top and bottom buckle actuators 350 and 352 to cause buckle 354 to release the strap 345 that is holding the water container from holding block 332. The strap may be a Velcro strap. The holding block 332 may be a suitable material such as Delrin. The containers vary in size and weight, e.g., approximately 4 to 12 pounds. In a particular example, the container is a plastic bottle filled with water and a shaped charge of C-4 explosive is placed facing the target. The orientation of the bottle is critical in order to be effective. Differing sizes of plastic bottles can be used depending upon the size of the target. The threaded rod 340 allows for adjustment in height to accommodate varying sizes of plastic bottles. Once the water container is in place, a blasting cap sets off the explosive via a detonation cord from the bottle to a user.
b) illustrates an opposite side view of water container placement system 300. While
In a fifth embodiment of the present invention shown in
As discussed above, the strap may be a Velcro strap. The holding block 404 may be a suitable material such as Delrin. Once the water container is in place, a separate actuation mechanism is employed to explode the water container such as via a blasting cap and detonation cord to the container controlled by the user. These trigger actuator mechanisms are known to those skilled in the art. Also as described above, the containers vary in size and weight, e.g., approximately 4 to 12 pounds. In a particular example, the container is a plastic bottle filled with water and a shaped charge of C-4 explosive is placed facing the target. The orientation of the bottle is critical in order to be effective. Differing sizes of plastic bottles can be used depending upon the size of the target. The threaded rod 416 allows for adjustment in height to accommodate varying sizes of plastic bottles.
b) illustrates an opposite side view of water container placement system 400. While
Referring to
c) shows an example of hook 604 (also representative of hook 312).
Referring to
The embodiments sets forth herein are intended to be exemplary. One skilled in the art recognizes the variations to the mechanical configurations, materials, and the like which are still considered to be within the scope of the invention. Further, though the embodiments are described and illustrated for use with particular robots, one skilled in the art recognizes that the tools may be used in conjunction with any robot having appropriate actuating components, e.g., arms, lowering mechanisms, etc.
This invention was made with Government support under contract no. N66001-06-D-5021, DO 0010 awarded by the Department of the Navy. The Government has certain rights in this invention.
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