An unmanned ground vehicle includes a main body, a drive system supported by the main body, a manipulator arm pivotally coupled to the main body, and a sensor module. The drive system includes right and left driven track assemblies mounted on right and left sides of the main body. The manipulator arm includes a first link coupled to the main body, an elbow coupled to the first link, and a second link coupled to the elbow. The elbow is configured to rotate independently of the first and second links. The sensor module is mounted on the elbow.

A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.

The present disclosure provides a robot security inspection method based on an environment map and a robot thereof. The method includes: establishing a two-dimensional planar map of an entire monitored region, planning a monitoring route, determining the position of the robot at the current monitored region, and moving to perform inspection according to the planed monitoring route. With the robot security inspection method based on an environment map and the robot thereof according to the present disclosure, traversing-based inspection may be performed according to the environment map, thereby preventing the dead space in the monitoring; dangerous factors may be proactively detected and security policy conformation may be conducted; the dangerous factors may be proactively tracked; and the robot is capable of normally operating even without auxiliary illumination at night.

A remotely controlled packable robot features a chassis, right and left main tracks for maneuvering the chassis, and right and left tracked rotatable flipper arms for maneuvering the chassis. An integrated drive assembly is provided for each main track and flipper pair and includes a motor in a housing attached to the chassis for rotating the flipper and a stator and rotor disposed about the motor housing for driving the main track and the flipper track.

A remotely controlled packable robot features a chassis with a top surface and a bottom surface, a pair of main tracks for maneuvering the chassis, and an open channel under the robot defined by the bottom surface of the chassis and the main tracks. A robot arm is foldable from a stored position in the open channel underneath the robot chassis to a deployed position extending upwards from the top surface of the chassis. A camera assembly may be foldable from a stowed position in the open channel underneath the robot chassis next to the robot arm to a deployed position extending upwards from the top surface of the chassis.

A modular mobile robot for use in association with a control unit includes a chassis, a pair of drive traction modules, a pair of drive transmission modules, a self-contained head module, a self-contained power module and a self-contained core module. The drive traction modules are operably attachable to the chassis. The drive transmission modules are operably connectable to the drive traction modules. The self-contained head module includes a power and data distribution system and is operably connectable to the drive transmission modules. The self-contained power module is operably connectable to the head module. The self-contained core module includes a main processor and communication system. The self-contained core module is operably connectable to the head module and the power module whereby the core module manages the communication with the control unit. The self-contained modules are designed to facilitate the easy repair and replacement of the modules in the modular mobile robot.

A mobile robot includes a deployment mechanism and a flexible tail. The flexible tail is attached to the deployment mechanism and extends outwardly from the mobile robot in a deployment direction. Actuation of the deployment mechanism moves the flexible tail and changes the deployment direction of the flexible tail. Movement of the flexible deployable tail allows the used to change the centre of mass of the mobile robot. As well in use the flexible deployable tail can help to stabilize the mobile robot when it is climbing stairs. As well, the flexible deployable tail can help the robot to absorb energy if it contacts a solid object.

A tooling arm includes a housing, a drive system, a lead screw and nut assembly, and a scoop assembly. The lead screw and nut assembly is operably connected to the drive system such that rotation of the nut drives the lead screw upwardly and downwardly relative to the housing. The scoop assembly is operably connected to the lead screw. The scoop assembly has an open position and a closed position and movement of the lead screw downwardly responsively moves the scoop assembly from the open position to the closed position.

An endless track is for use with a mobile robot and includes a belt, a plurality of chamfered cleats, a plurality of holes and a dual v-guide. The belt has an inner surface and an outer surface. The plurality of chamfered cleats, each have a contact surface. The chamfered cleats are attached to the outer surface defining an attachment area, and the contact surface is shaped such that when the track is laid on a flat solid surface, each chamfered cleat contacts the flat solid surface with less area than the attachment area. The plurality of holes in the belt are disposed between the chamfered cleats and are shaped to allow teeth of a drive sprocket pulley to pass through and to engage the belt for transmitting force from the sprocket pulley to the belt. The dual v-guide includes two elongate, parallel protrusions which are spaced laterally from each other and are attached to the inner surface.

Systems and methods for randomized autonomous robot security applications may include a security system that generate a patrol area of a facility and select a random waypoint from a plurality of waypoints in the patrol area for an autonomous mobile machine to surveillance. The security system may also select a surveillance task to be performed by the autonomous mobile machine at the random waypoint, and transmit, to the autonomous mobile machine, instructions to visit the random waypoint and perform the surveillance task. When the security system receives, from the autonomous mobile machine, an indication that the autonomous mobile machine has completed the surveillance task at the random waypoint, the security system may transmit a subsequent random waypoint of the plurality of waypoints of the patrol area along with a subsequent surveillance task to be performed at the subsequent random waypoint.