A cooking system includes a grill, a first arm assembly and a second arm assembly. An electronic hardware controller is in signal communication with the at least one grill, the first arm assembly and the second arm assembly. The controller operates the first arm assembly to transfer a prepared product to the grill, and operates the second arm assembly to transfer a cooked product from the grill.

An assistive robot system includes a lifting mechanism, a movable arm assembly, a processing device, and a non-transitory, processor-readable storage medium in communication with the processing device. The processing device transmits a command to the lifting mechanism to cause the lifting mechanism to move the movable arm assembly such that a container is gripped within the movable arm assembly, transmits a first one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system longitudinal direction such that the movable arm assembly grips the container. The movable arm assembly is positioned at a release location and transmits a second one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system lateral direction such that the container gripped within the movable arm assembly is released from the movable arm assembly at the release location.

This box assembling and packing system is provided: a first jig which is fixed at a predetermined position and against which a side part of a body of a packing box is thrust; a second jig which is fixed at a predetermined position and against which a flap part and a tuck part of the packing box are thrust; and a robot having two articulated arms. A first articulated arm of the two articulated arms holds and moves the packing box in a flatly collapsed form by a packing box holding mechanism, folds and raises the body of the flatly collapsed packing box into a rectangular tubular shape in cooperation with the first jig, and maintains the folded and raised body of the packing box in the rectangular tubular shape by a packing box rectangular tubular shape maintaining mechanism. The second articulated arm moves a folding member into contact with the flap part and the tuck part of the packing box being held by the packing box holding mechanism of the first articulated arm, forms each of a bottom and a lid of the packing box in cooperation with the second jig, and moves an object-to-be-packed being grasped by an object-to-be-packed grasping mechanism and inserts it into the body from an end portion at a timing between forming the bottom and forming the lid.

Methods, systems, and robots for multi-layer prepreg composite sheet layup. The method includes obtaining a dataset including start and end point pairs of a mold of the 3D part. The method includes generating a layup sequence based on the dataset and generating multiple trajectories for one or more movements of the first robot or the first robot arm based on the layup sequence. The method includes causing a second robot or a second robot art to hold or grasp the prepreg layer or sheet a threshold distance above the mold or the 3D part. The method includes causing the first robot or the first robot arm to place or conform the prepreg layer or sheet to the mold of the 3D part.

The innovation is a replica of hands to massage and bring comfort and relaxation; and largely replace the need for a masseuse or masseur. Features are incorporated into the innovation include being strong, agile, and light.

Systems and methods for multi-armed robotic capture devices are disclosed. The systems and methods for multi-armed robotic capture devices include a base that is configured to attach to a robotic arm or a servicer and having a tether. The systems and methods for multi-armed robotic capture devices include a body that is coupled to the base via the tether. Additionally, the systems and methods for multi-armed robotic capture devices include a plurality of tentacles coupled to the body and configured to grip a target object. The systems and methods for multi-armed robotic capture devices also include a plurality of tiles positioned on each tentacle of the plurality of tentacles and configured to apply a shear force on the target object to grip the target object using an adhesive force.

Systems, methods, and computer-readable media are disclosed for container transporters and related item manipulation devices. In one embodiment, an example item manipulation device may include a support platform, and a conveyance surface attached to the support platform and configured to convey a container at least a portion of a distance from a first side of the support platform to a second side of the support platform, where the conveyance surface defines at least a portion of a container passage through which a container can be conveyed. The item manipulation device may include a manipulator comprising a first arm disposed along a longitudinal axis of the item manipulation device and a second arm disposed along the longitudinal axis of the item manipulation device, where the manipulator is engageable with the container to move the container at least partially onto the conveyance surface.

A control arm assembly for controlling a robot system includes a gimbal that is moveable and rotatable about three axes, and a handle assembly coupled to the gimbal. The handle assembly includes a body portion having a controller disposed therein and a first actuator disposed thereon. The first actuator is mechanically coupled to the controller via a four-bar linkage such that actuation of the first actuator causes mechanical movement of a component of the controller which is converted by the controller into an electrical signal.

A dual-manipulator control method is configured to be used in a dual-manipulator control system including a first manipulator, a second manipulator, and a central control module. The first manipulator and the second manipulator are controlled by the central control module, and the central control module is configured to execute the dual-manipulator control method. The dual-manipulator control method includes: generating a first instruction sequence to control the first manipulator and a second instruction sequence to control the second manipulator; and controlling the first manipulator and the second manipulator based on the first instruction sequence and the second instruction sequence. Thus, the working efficiency is improved.

A robot includes a robot arm formed with an ingredient channel including an ingredient inlet and an ingredient outlet; an ingredient feeder having an ingredient port configured to discharge ingredients; and a carrier configured to move the robot arm to a connection position where the ingredient inlet is connected to the ingredient port, and move the robot arm to an area where the ingredient inlet is separated from the ingredient port.