A robot includes a rail system, a body structure coupled to the rail system, a first arm coupled to a first side of the body structure, one or more first arm actuators providing the first arm with multiple degrees of freedom, a second arm coupled to a second side of the body structure, one or more second arm actuators providing the second arm with multiple degrees of freedom, a lift actuator operable to move the body structure along the rail system, and a tilt structure coupled to the body structure. The first arm actuators and the second arm actuators are operable to wrap the first arm and the second arm around an object and hold the object against the body structure. The tilt structure is operable to tilt the body structure. The lift actuator is operable to move the body structure such that the object is lifted.

Robots for lifting objects are disclosed. In one embodiment, a robot includes a rail system, a body structure coupled to the rail system, a first arm coupled to a first side of the body structure, one or more first arm actuators providing the first arm with multiple degrees of freedom, a second arm coupled to a second side of the body structure, one or more second arm actuators providing the second arm with multiple degrees of freedom, and a lift actuator operable to move the body structure along the rail system. The one or more first arm actuators and the one or more second arm actuators are operable to wrap the first arm and the second arm around an object and hold the object against the body structure. The lift actuator is operable to move the body structure such that the object is lifted on the rail system.

Structures and sensor assemblies having engagement structures for securing a compliant substrate assembly are disclosed. In one embodiment, a sensor assembly includes a compliant substrate assembly having a base layer, and a deformable layer heat-sealed to the base layer such that the base layer and the deformable layer define at least one inflatable chamber. The sensor assembly further includes a first member proximate to a first edge of the compliant substrate assembly, a second member proximate to a second edge of the compliant substrate assembly, wherein the second edge is opposite the first edge, and at least one pressure sensor fluidly coupled to the at least one inflatable chamber and operable to produce a signal indicative of a pressure within the at least one inflatable chamber.

An automated robot design pipeline facilitates the overall process of designing robots that perform various desired behaviors. The disclosed pipeline includes four stages. In the first stage, a generative engine samples a design space to generate a large number of robot designs. In the second stage, a metric engine generates behavioral metrics indicating a degree to which each robot design performs the desired behaviors. In the third stage, a mapping engine generates a behavior predictor that can predict the behavioral metrics for any given robot design. In the fourth stage, a design engine generates a graphical user interface (GUI) that guides the user in performing behavior-driven design of a robot. One advantage of the disclosed approach is that the user need not have specialized skills in either graphic design or programming to generate designs for robots that perform specific behaviors or express various emotions.

Embodiments of the present disclosure provide a robot. The robot arm link includes a first arm link; a hollow shaft extending along a first axis thereof and coupled to the first arm link; a first stage reduction assembly coupled to a power source of the robot; and a second stage reduction assembly comprising: an input coupled to an output of the first stage reduction assembly and adapted to rotate about a second axis offset from the first axis; and an output coaxially arranged on a periphery of the hollow shaft and adapted to engage with the input to cause a rotation of the first arm link via the hollow shaft.

A secondary battery unit includes a first secondary battery module disposed at at least either one of a front part or a back part of a body of a humanoid robot, a second secondary battery module disposed around the body in a direction intersecting with a front-and-rear direction of the body, and a base coupling the first secondary battery module to the second secondary battery module. The base is detachably attached to the body, together with the first secondary battery module and the second secondary battery module.

Presented are embodiments of a modular transport robot for transporting consignments. The transport robot includes at least one base element for the structure of the transport robot, at least two expansion modules for the technical equipping of the transport robot, at least one consignment box for receiving consignments, and at least one control device. The base element and each of the expansion modules have corresponding connecting elements and are electrically connected to one another by an electrical connection. The base element has at least one wiring harness for electrically connecting the connecting elements of the base element to one another, and the base element and the expansion modules are designed correspondingly to one another such that the connecting elements of the expansion modules are selectively connectable directly to at least two connecting elements provided at different points, so as to form one common connection to the base element.

Embodiments of the present disclosure provide a plastic robot arm link. The robot arm link comprises a body made of plastic material; a connection arranged on the body and adapted to be coupled to a further plastic robot arm link or a transmission part of the robot; and an insertion made of material with a higher strength or stiffness than the plastic material and embedded in the body and/or the connection. By embedding the material with higher strength or stiffness within the body of the robot arm link made of plastic material, the stiffness and strength of the robot arm link can be enhanced. In addition, due to the presence of highly rigid materials, the creep effect of the plastic arm is also significantly reduced, improving the accuracy of the robot.

A method of manufacturing a robotic manipulator including determining desired manipulator properties including a manipulator shape and manipulator jamming properties; using the manipulator jamming properties and a packing computational model to determine a packing element configuration, the packing computational model defining relationships between manipulator jamming properties and different packing element configurations; controlling an additive printing machine based on the packing element configuration and manipulator shape to manufacture the robot manipulator. The robot manipulator includes a flexible outer skin defining a chamber; a connector attached to the outer skin and connected to a fluid pump to allow fluid to be added to or removed from the chamber; filling elements disposed in the chamber according to the packing element configuration.

A support frame for a handling device comprising a base body and at least two structural elements extending away from the base body, at least two structural elements being constructed similarly to each other in that they have at east the following common characteristics: a radial beam which is elongated and has a first end and a second end, the second end having a connecting section for connection to a pneumatically actuatable gripping element, a lattice wing which is integrally connected with the radial beam and runs between the first end of the radial beam and the second end of the radial beam, the lattice wing extending flatly away from the radial beam, wherein for each of the at least two structural elements the first end of the radial beam is integrally connected with the base body in a manner that the radial beam extends away from the base body.