The present invention relates to robots. More particularly, the present invention relates to collapsible surveillance robots configured to carry a payload, as well as accessories and drive configurations for surveillance robots.
During combat and other situations when an adversary may be encountered, obtaining visual surveillance of the surrounding environment can be beneficial. Gaining an appropriate visual vantage point, however, often places individuals and equipment in harm's way. For example, peering through a doorway to look into an adjacent room can expose an individual to hostile fire. Personnel ascending and descending stairwells and entering attic spaces can be similarly exposed to hidden or unexpected dangers.
Outdoor environments can provide similar obstacles to visual surveillance which, when circumnavigated or avoided, may expose an individual to hostile fire. Such obstacles can include, for example, walls, fences, berms, buildings, rock formations, and the like.
Existing surveillance equipment for providing indirect visualization of a desired environment varies in complexity from extendable mirrors to mobile robots. The use of robotic surveillance systems is becoming increasingly common in hostile environments. The robots used in these surveillance systems are utilized to provide visual images. After delivery into an area to be surveilled, such as by throwing, the robots can be remotely maneuvered with an operator control unit to position the robot and embedded camera as desired by a user. A drawback of these devices is that their use is limited by the availability of terrain (i.e., a ground surface) or objects that can support the robot. A further drawback is that once positioned into a hostile environment, retrieval of the robot can be limited or impractical due to the presence of adversaries and physical obstacles that cannot be overcome after delivery, such as occurs when a robot is thrown over a wall.
Existing surveillance equipment is also highly customized for a specific task. The use of robotic surveillance systems can provide visual images or audio surveillance, however existing devices no not lend themselves to being customized to meet the varying needs that may be encountered in a hostile military or law enforcement environment.
Additional information regarding two-wheeled robots can be found in U.S. Patent Publication No. 2010/0152922, and U.S. Pat. No. 7,559,385, each of which is incorporated herein by reference.
One embodiment of the present invention includes a robotic vehicle capable of collapsing into a small form factor for ease of transportation and providing for a quick transition to a deployed configuration. The vehicle can be configured to carry a payload when deployed.
Examples of payloads can include sensor packages, battery packages, weapons, or explosives, such as a shaped charge, including a water based shaped charge usable, for example to detonate or disable improvised explosive devices (IEDs) in ground based vehicles or the like.
One embodiment of the present invention includes interchangeable spoke elements that can hinge at a pin element on a wheel hub to fold against the body of the robotic vehicle for storage or transport. The body of the robotic vehicle can include various electronic controls, sensors, one or more batteries, and a motor and drive mechanism coupled to a pair of hubs. The spoke elements can also fold out, and secured in a deployed radial configuration, generally perpendicular to the body of the vehicle to form a wheel like assembly. The spoke elements are maintained in either their folded or deployed configuration by an end cap assembly that can be removably attached to a wheel hub with a fastening mechanism. Various spoke elements can be interchangeably connected to the body of the robotic vehicle depending on the desired wheel radius or the type of terrain where the vehicle is to be deployed.
One embodiment of the present invention includes arm assemblies that can house an electric motor attached to each side of a body of a robotic vehicle. The arm assemblies can rotate approximately 90 degrees between a deployed and a folded (or stowed) configuration. Coupled to the arm assembly is a gearbox that can detachably couple a wheel to the motor. A payload can be attached to the underside of the body of the robotic vehicle. Wheels of various diameter can be coupled to the gearbox thereby accommodating payloads of different dimensions when attached to the robot body. The robot body can also be coupled to a tail or counterweight to provide stability and maintain an upright orientation of the robotic vehicle.
One embodiment of the present invention includes a bracket assembly sized and configured to fit around the body of a robotic vehicle. The bracket assembly can be coupled to the robotic vehicle and provide a mounting point or tab assembly configured to mate with a payload. Examples of payloads can include sensor packages, battery packages, weapons, or explosives, such as a shaped charge, including a water-based shaped charge usable, for example to detonate or disable improvised explosive devices (IEDs) in ground based vehicles or the like.
The embodiments of the present invention may be more completely understood in consideration of the following detailed description of various embodiments of the invention in connection with the accompanying drawings, in which:
While the present invention is amendable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the present invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the present invention,
The robotic vehicle 100 includes two wheel assemblies 106 for locomotion and a tail assembly 108 for stabilization and orientation of the body 102. In one embodiment the wheel assemblies 106 and body 102 of the robotic vehicle 100 are sized such that the payload 104 is suspended approximately six-inches above the surface the robotic vehicle 100 is disposed upon. In one embodiment an exemplary payload has external dimensions of approximately 32 centimeters in length, 5 centimeters in width×8 centimeters in depth and a weight of approximately 1 kilogram.
The wheel assemblies 106 include foldable wheel spokes 110 that are hinged on a wheel hub 112. When the wheel spokes 110 are deployed the wheel assemblies 106 and wheel hub 112 rotate relative to an axis of the robot vehicle body 102, providing locomotive force to propel the robot vehicle 100. The use of alternate length spokes 110 can vary the height at which the payload 104 is suspended within a range of one to eighteen inches above the surface the robot device 100 is disposed upon.
The foldable wheel spokes 110 can include spoke ends 114 that can be shaped to conform to the exterior shape of the robot body 102, allowing for a compact packed form. The spoke ends 114 can include firm rubberized feet, solid metallic or plastic feed, or any of a variety of materials to provide traction on whatever surface the robot vehicle 100 is disposed. The spoked design of the wheels enables locomotion over difficult terrain and the scaling of obstacles in the path of the robotic vehicle 100.
An end cap 116 can secure the spokes 110 in either a folded (collapsed) or unfolded (deployed) position by supporting the spoke 110 at some distance from its pivot point. When in the folded position, as depicted in
Referring again to
Referring to
The robot vehicle 100 can also include a variety of electronic components for the reception and transmission of control and sensor data, a battery and supporting electronics to supply power at varying voltages and ensure safe operation, and one or more sensors such as a camera 132. An exemplary electronics package 136 and motor drive train assembly 140 are depicted in
The robot can be easily converted from its packed configuration to its deployed configuration or vice versa by an operator with minimal training. Referring to
Referring to
Referring to
The robot 100 can be controlled and monitored remotely with a complementary handheld unit operated by a user with minimal training. An exemplary unit is depicted in
A robot device 200 according to an embodiment of the present invention is depicted generally in a deployed form in
The robot device 200 can carry a payload 204 when deployed, which can be placed below the body 202 or electronics enclosure of the device 200 and secured via hook-and-loop straps or another fastening mechanism such as a detachable bracket or other fasteners. In one embodiment the wheel assemblies 206 and body 202 of the robotic device 200 are sized such that the payload 204 is suspended approximately six-inches above the surface the robotic device 200 is disposed upon. The use of alternate diameter wheels 210 or wheel assemblies 206 can provide a height at which the payload 204 is suspended in a range of one to eighteen inches above the surface the robot device 200 is disposed upon.
The robot device 200 can be utilized for robotizing a payload 204, enabling the payload 204 to be delivered to a destination remotely by the communication of commands to the robot device 200 by an operator or autonomously by programming the robot device 200 to follow a sequence of preprogrammed commands.
Two wheels 210 and a driving means, such as electric motors 214, a tail 208, and supporting electronics in the body 202 are attached to a payload 204. The drivetrain can be integrated on arms 212 which are hinged on the exterior of the body 202. When packed, the arms 212 are positioned to lie in plane with the flat surface of the body 202, while the tail 208 and wheels 210 can be stored unassembled.
The wheel assemblies 206 include a removable wheel 210 mounted to an arm 212. Arm 212 can include a motor 214 and drive assembly or gear mechanism 216 coupled to the wheel 210 to propel the robot device 200. The arm 212 can rotate on a pivot 218 that connects the arm 212 to the body 202 of the robot device 200. Arm 212 can include a retractable spring plunger 220 that can secure the arm 212 in either the deployed and stowed position while allowing easy transition from stowed to deployed and the reverse. When deployed, the arms are rotated approximately 90 degrees and engage with a snap or locking feature (shown in
Referring to
Referring to
The robot can be controlled and monitored remotely with a complementary handheld unit 400 operated by a user with minimal training. The handheld unit 400 can include antenna 402, transmitters and receivers complementary to the robot's transmitters and receivers, an interface such as a video screen 404 to monitor the robot, and a control interface such as a joystick 406 or set of buttons 408. The handheld until 400 can also include specialized transmitters configured for used with an explosives payload that can be attached to the robot. In one embodiment the explosives package can be configured to destroy both a target IED and the robot 200 simultaneously.
Referring to
The robotic vehicle 300 includes a body 302 uses two wheels 310 for locomotion and a tail 308 for stabilization of the body's orientation. In one embodiment the wheel assemblies 310 and body of the vehicle 300 are sized such that the payload 304 is suspended approximately six-inches above the surface the vehicle is disposed upon. The wheel assemblies 310 can be detached from the body 302 to allow the installation of bracket 301. An attachment-mounting bracket 301 for a miniature robot 300 enables the robot 300 to carry payload 304. The bracket 301 enables a robot to be equipped with a payload 304 without requiring access to the internal components of the robot 300. The internal components can include one or more motors, batteries, sensors and the like.
The bracket 301 has attachment points for the robot body 302 and the payload 304. The counterweight 303 has attachment points to connect to a portion of the robot 300 on the opposite side of the robot 300 from the payload 304. For example, if the payload 304 is on the front of the robot 300, the counterweight 303 can be placed on the back, for example on the end of a tail 308. The counterweight 303 serves to balance the weight of the payload 304 improving the dynamic performance of the robot 300 and enabling the use of the counterweight 303 while maintaining the correct orientation. As depicted in
The ring 305 of bracket 301 can be replaced by a snap-on clip to eliminate the need to remove the wheels to assemble the attachment. The ring can be secured to the body 302 of the robot vehicle 300 with a screw or other fastening mechanism. The payload 304 can be attached to the bracket with screws or another appropriate fastening mechanism. Payload 304 can include a bracket 315 forming a slot 317 that is sized to receive tab 319. Tab 219 can be coupled to bracket 301 with fasteners or be included as an integrated component of an alternate embodiment of the bracket.
In one embodiment, the vehicle can receive commands from the remote computer 400 via an onboard 4-channel R/C receiver, utilizing two channels for motor control and two for other functions. In one embodiment the joystick 406 can include a switch that is activated when the joystick 406 is depressed. While the joystick 406 is depressed an operator can adjust the brightness of the display screen 404. The ability to adjust the brightness of display screen 404 can allow the operator to improve visibility of the display screen 404 in bright daylight conditions by depressing the joystick 406 and moving the joystick 406 upwards, towards the display screen 404. Conversely, in low light conditions, or when the operator does not wish to draw attention to himself, the operator can depress the joystick 406 and move the joystick 406 downwards, away from the display screen 404. A programmable controller in the computer 400 can include a software program stored in tangible computer-readable memory to interpret these brightness commands and adjust the intensity of the display screen (or appropriate backlight) in response to the manipulation of joystick 406.
The embodiments above are intended to be illustrative and not limiting. Additional embodiments are within the claims. In addition, although aspects of the present invention have been described with reference to particular embodiments, those skilled in the art will recognize that changes can be made in form and detail without departing from the spirit and scope of the invention, as defined by the claims.
Persons of ordinary skill in the relevant arts will recognize that the invention may comprise fewer features than illustrated in any individual embodiment described above. The embodiments described herein are not meant to be an exhaustive presentation of the ways in which the various features of the invention may be combined. Accordingly, the embodiments are not mutually exclusive combinations of features; rather, the invention may comprise a combination of different individual features selected from different individual embodiments, as understood by persons of ordinary skill in the art.
Any incorporation by reference of documents above is limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein. Any incorporation by reference of documents above is further limited such that no claims included in the documents are incorporated by reference herein. Any incorporation by reference of documents above is yet further limited such that any definitions provided in the documents are not incorporated by reference herein unless expressly included herein.
The present application claims priority to U.S. Provisional Patent Application Nos. 61/380,161, 61/380,163, and 61/380,167, filed on Sep. 3, 2010, each of which is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
61380163 | Sep 2010 | US | |
61380161 | Sep 2010 | US | |
61380167 | Sep 2010 | US |