A robotic device including one or more proximity sensing systems coupled to various portions of a robot body. The proximity sensing systems detect a distance of an object about the robot body and the robotic device reacts based on the detected distance. The proximity sensing systems obtain a three-dimensional (3D) profile of the object to determine a category of the object. The distance of the object is detected multiple times in a sequence to determine a movement path of the object.

A device forming a robotic hand, including a base forming a hand palm, at least two articulated structures each forming a robotic finger, each articulated structure being connected to the base by at least one articulation, at least one drive mechanism for each articulation, at least one actuator arranged to actuate the at least one drive mechanism by means of at least one flexible drive link connecting and driving the at least one drive mechanism, structure for measuring the pivoting of the at least one actuator and one or more of the articulations, a glove covering the base and the at least two articulated structures, the glove being closed so as to form, inside the glove, a volume filled with oil between the wall of the glove and the base and the at least two articulated structures. Robotic hands used in aquatic environments at great depths are also disclosed.

A portable robotic semiconductor pod loader may detect, with at least one sensor, receipt of a semiconductor pod on a load port of the portable robotic semiconductor pod loader. The at least one sensor is supported by the load port. The portable robotic semiconductor pod loader may cause a robot, of the portable robotic semiconductor pod loader, to align with the semiconductor pod provided on the load port. The portable robotic semiconductor pod loader may cause the robot to attach to the semiconductor pod, and may cause the robot to provide the semiconductor pod from the load port to a staging area of a semiconductor processing tool.

A substrate mapping device 4 maps a plurality of substrates 10 inside a container where the substrates 10 are accommodated so as to be arrayed in a given arrayed direction. The substrate mapping device 4 includes a sensor 16 configured to detect a state of the substrate 10, a manipulator 14 configured to move the sensor 16, and a control device 18 configured to control the manipulator 14 to move the sensor 16 along a mapping course. The control device 18 sets a first mapping position and a second mapping position different in the position in the arrayed direction of the substrates 10 from the first mapping position, and sets the mapping course based on the first mapping position and the second mapping position.

A non-destructive inspection system is presented. The non-destructive inspection system comprises a robotic end effector having an extendable actuator and a flange-mounted roller containing an ultrasonic sensor, the flange-mounted roller connected to the extendable actuator by a pivot connection, the extendable actuator configured to extend the flange-mounted roller until the flange-mounted roller contacts an inspection surface.

A robotic device for distributing designated items to designated persons, includes: a motion unit to autonomously move said robotic device; storage means including multiple compartments; an item dispenser to dispense items from said storage means; a memory module containing optical recognition scans and personal information of persons located within a premise, and substantive information of the designated items; optical recognition scanners; a control module in communication with the motion unit, the optical recognition scanners, the memory and the item dispenser. The control unit directs movement of the robotic device, directs the optical recognition scanners to scan persons, and compares images from the optical recognition scanners to optical recognitions in the memory. Upon identifying a person, the control unit searches personal information of the person and identifies designated items specified for that person, and then directs the item dispenser to dispense the designated item.

Inspection robots and methods for inspection of curved surfaces with sensors at selected horizontal distances are described. An example of such an inspection robot includes a housing; a drive module with a wheel and a motor operatively linked to the housing, a plurality of sensor sleds, and a payload. The payload, which is coupled to the housing, may include a first and a second rail component, each with at least one connector, where the rail components are connectable at a first selected position of a plurality of discrete engagement positions. Each of the rail components may be structured to support at least one of the plurality of sleds where each of the plurality of sleds is coupled to the payload at a respective selected horizontal position such that the plurality of sleds are at selected horizontal distances from each other.

A robot system is configured to identify gestures performed by an end-user proximate to a work piece. The robot system then determines a set of modifications to be made to the work piece based on the gestures. A projector coupled to the robot system projects images onto the work piece that represent the modification to be made and/or a CAD model of the work piece. The robot system then performs the modifications.

An arm module includes a housing with a first connection side controllably rotatable relative to a second connection side, about an axis of rotation. The first connection side has a rotatable first connection device. The second connection side has a second connection device fixed to the housing, with a rotation-compatible data transmission device for transmitting data signals along at least one transmission path between the first and second connection sides. The transmission path includes at least one wireless transmission sub-path for wireless transmission of data signals, and at least one wire-guided transmission sub-path for wire-guided transmission of data signals. The rotation-compatible data transmission device includes at least one first wireless transmission unit and at least one second wireless transmission unit, interconnected via the transmission path and arranged to wirelessly transmit and receive data signals along the wireless transmission sub-path. An industrial robot can have a plurality of such arm modules.

A fluid exchanging system and method for use in exchanging fluids in insulating glass units (IGUs). The fluid exchanging system includes an articulating arm having a plurality of members and arms to allow movement about multiple axes defined by the articulating arm, an optical sensor system, coupled to the articulating arm, for identifying an opening in a spacer frame of an IGU, and a fluid exchanging apparatus releasably couplable to the articulating arm. The fluid exchanging apparatus also includes a fluid exchanging head for evacuating atmospheric air from the IGU and dispensing fluid into the IGU.