A robot includes heat-generating members such as an actuator in spaces surrounded by exterior members. A heat-transfer section transfers heat of the heat-generating members to the exterior members. A heat-transfer control section adjusts the amount of heat transfer between the heat-generating members and the exterior members by operating the heat-transfer section. The heat-transfer section has a thermally conductive member that can shift between a coupling position for thermally coupling the heat-generating members and the exterior members, and an interrupting position for interrupting thermal conduction between the heat-generating members and the exterior members.

A robot includes a robot arm, a base supporting the robot arm, and a cable coupled to the base, wherein the base has a housing a circuit board, a connector unit located on a side surface of the housing and electrically coupled to the circuit board, to which the cable is coupled, a cover member having an insertion portion through which the cable is inserted and attached to the side surface of the housing to cover the connector unit, and a wall portion located between a coupling portion by which the cover member is coupled to the side surface of the housing and the connector and provided to project from the side surface of the housing within a space surrounded by the side surface of the housing and the cover member.

An apparatus including a movable arm; a robot drive connected to the movable arm; and a heat transfer system. The robot drive includes a first drive configured to extend and retract the movable arm and a second drive configured to move the movable arm and the first drive along a linear path. The heat transfer system includes a first heat transfer member on the base and a second heat transfer member, where the heat transfer system is configured to transfer heat from the first drive to the first heat transfer member and then from the first heat transfer member to the second heat transfer member. The first heat transfer member travels with the base, and the first heat transfer member moves relative to the second heat transfer member as the base moves relative to the slide.

A parallel type integrated actuator is proposed. The actuator includes: a driving unit composed of a plurality of motors, each motor being stacked successively in a longitudinal direction of the driving unit, each motor having a stator fixed to a position outside the driving unit and a rotor positioned inside thereof, each motor rotating relative to each other; a plurality of shafts; a heat sink housing having a cylindrical shape formed around the outer surface of the driving unit, and having an inner circumferential surface thereof thermally connected with the plurality of stators and a plurality of flow paths formed on the outer circumferential surface thereof; and a blower fan installed on one end side of the driving unit, provided with a wing part disposed to be adjacent to one end side of the heat sink housing, wherein rotation generates convection for heat exchange.

A guidance robot according to an embodiment of the present disclosure includes a display, a head case configured to be provided to be capable of rotating, an upper case configured to couple to the display and the head case, the upper case being configured to receive an electronic component and a cooling fan therein, and a lower case configured to be located on a lower side of the upper case, the lower case being configured to locate a wheel and a motor therein. In addition, when the cooling fan is driven, outside air is suctioned through a gap between a lower end portion of the head case and an upper-end portion of the upper case, and the suctioned air passes through the electronic component and then is discharged to the outside through the gap between the lower end portion of the upper case and the upper-end portion of the lower case.

A heat dissipating system of movable robot is provided. The heat dissipating system includes a movable robot and at least one wind resistance structure. The movable robot includes a housing, at least one airflow passage and plural first air holes. The housing defines an inner space, the airflow passage is disposed in the inner space, and the first air holes are disposed on the housing and are in communication with the airflow passage respectively. When the movable robot moves, an air current is generated accordingly. The air current partially flows into the airflow passage through the first air hole acted as an inlet, and the air current in the airflow passage is released from the first air hole acted as an outlet. The wind resistance structure is configured for guiding the air current into the first air hole acted as the inlet.

An apparatus including a movable arm; a robot drive connected to the movable arm; and a heat transfer system. The robot drive includes a first drive configured to extend and retract the movable arm and a second drive configured to move the movable arm and the first drive along a linear path. The heat transfer system includes a first heat transfer member on the base and a second heat transfer member, where the heat transfer system is configured to transfer heat from the first drive to the first heat transfer member and then from the first heat transfer member to the second heat transfer member. The first heat transfer member travels with the base, and the first heat transfer member moves relative to the second heat transfer member as the base moves relative to the slide.

The invention discloses a mobile robot configured for delivering consumable items to delivery recipients. The mobile robot comprises an item compartment with a top section, a separator, and a bottom section. The mobile robot also comprises a temperature control component. The invention also discloses a method for delivering consumable items to delivery recipients using the mobile robot.

An apparatus including a movable arm; a robot drive connected to the movable arm; and a heat transfer system. The robot drive includes a first drive configured to extend and retract the movable arm and a second drive configured to move the movable arm and the first drive along a linear path. The heat transfer system includes a first heat transfer member on the base and a second heat transfer member, where the heat transfer system is configured to transfer heat from the first drive to the first heat transfer member and then from the first heat transfer member to the second heat transfer member. The first heat transfer member travels with the base, and the first heat transfer member moves relative to the second heat transfer member as the base moves relative to the slide.

A manufacturing cell for welding a workpiece includes a robotic arm extending between a base and a terminal end, a weld head coupled to the terminal end of the robotic arm such that the weld head is permitted to travel relative to the base of the robotic arm, wherein the weld head is configured to weld the workpiece, a sensor pod coupled to the weld head and including an outer pod housing defining an internal chamber extending between a front end and a rear end of the pod housing, and wherein the front end of the pod housing defines a receptacle, a sensor positioned in the internal chamber of the pod housing, the sensor configured to provide sensor feedback associated with the workpiece, and a consumable window including a transparent material is insertable into the receptacle such that a longitudinal axis of the sensor intersects the consumable window when the consumable window is inserted into the receptacle, and a controller coupled to the sensor pod and configured to operate at least one of the robotic arm and the weld head based on the sensor feedback provided by the sensor of the sensor pod.