Provided is a robot system which includes: a robot; a controller controlling the robot and causing the robot to operate in a plurality of operation modes; and a display device attached on the robot and caused by the controller to operate in patterns in accordance with the operation modes, the patterns being different from one another. The display device includes: a sheet-like base part being deformable in a shape in accordance with an outer surface of the robot and having flexibility; one or more display parts fixed on the base part; and a fixture maintaining the base part in a state in which the base part is attached on the outer surface of the robot.

A two wheeled throwable robot comprises an elongate chassis with two ends, a motor at each end, drive wheels connected to the motors, and a tail extending from the elongate chassis. The throwable robot includes a pair of torque limiting mechanisms, each torque limiting mechanism being operatively coupled between a motor and a drive wheel. Each torque limiting mechanism comprises a drive flange portion, a driven flange portion and a plurality of rollers. A spring element provides a ring force that biases the rollers toward the driven flange portion.

An inspection robot, and methods and a controller thereof are disclosed. An inspection robot may include an inspection chassis including a plurality of inspection sensors and coupled to at least one drive module to drive the robot over an inspection surface. The inspection robot may also include a controller including an inspection data circuit to interpret inspection base data, an inspection processing circuit to determine refined inspection data, and an inspection configuration circuit to determine an inspection response value in response to the refined inspection data. The controller may further include an inspection response circuit to, in response to the inspection response value, provide an inspection command value while the inspection robot is interrogating the inspection surface.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

A heat dissipation device and a robot using the same are provided. The heat dissipation device comprises a porous material layer, a transporting tube and a liquid. The at least one porous material layer is disposed on a housing surface of a robot. The porous material layer has an evaporation surface and an accommodation space. The evaporation surface is disposed through and exposed from the housing surface. The evaporation surface and the accommodation space are in fluid communication with each other. The transporting tube is connected to the at least one porous material layer and in fluid communication with the accommodation space. The liquid is transported into the at least one accommodation space through the transporting tube and exposed from the evaporation surface. Thus, the liquid evaporates at the evaporation surface to reduce a temperature of the housing surface of the robot via convection and evaporation.

According to at least one aspect, the present disclosure provides a robot system for automatically assembling a modular component and an assembly target, comprising: an assembly robot including a first manipulator, an assembly tool coupled to the first manipulator and configured to assemble the modular component and the assembly target, and a first camera configured to capture images in a direction in which the assemble tool faces; a loading robot including a second manipulator and a gripper coupled to the second manipulator and configured to grip the modular component; and a control device configured to control the assembly robot and the loading robot.

Techniques are disclosed for systems and methods for providing a wired connection between a ground-based robot and a controller. A cable handling system for a robot may include a base housing, a cable cartridge removably connected to the base housing, a control cable housed at least partially within the cable cartridge, and an outfeed assembly coupled to the base housing and configured to deploy the control cable from the cable cartridge. The control cable may be deployable from the cable cartridge to maintain a wired connection between the robot and a controller. The outfeed assembly may be configured to couple to a drive mechanism of the robot such that movement of the drive mechanism deploys the control cable from the cable cartridge. The outfeed assembly may be configured to deploy the control cable from the cable cartridge regardless of the direction of movement of the drive mechanism.

Techniques are disclosed for systems and methods for providing a wired connection between a ground-based robot and a controller. A cable handling system for a robot may include a base housing, a cable cartridge removably connected to the base housing, a control cable housed at least partially within the cable cartridge, and an outfeed assembly coupled to the base housing and configured to deploy the control cable from the cable cartridge. The control cable may be deployable from the cable cartridge to maintain a wired connection between the robot and a controller. The outfeed assembly may be configured to couple to a drive mechanism of the robot such that movement of the drive mechanism deploys the control cable from the cable cartridge. The outfeed assembly may be configured to deploy the control cable from the cable cartridge regardless of the direction of movement of the drive mechanism.

An exoskeleton system comprising at least one actuator unit that includes a fluidic actuator; an exoskeleton device including a fluidic system, and electronics; and a first cable extending from the exoskeleton device to the at least one actuator unit.

An exoskeleton system comprising: one or more actuator units that comprise a fluidic actuator; an exoskeleton device; one or more cables, the one or more cables comprising a first cable extending from the exoskeleton device to a first actuator unit of the one or more actuator units; and a retractable cable assembly coupled to the first cable, with the retractable cable assembly configured to pull the first cable to reduce slack in the first cable.