The present invention relates to a robotic maneuvering system for maneuvering objects by means of an adhesive attachment. The robotic maneuvering system comprises a gripper finger connected to a gripper arm. The gripper finger is configured to grasp an object to be manipulated, by means of an adhesive contact. The gripper arm maneuvers the object to a desired location and the gripper finger releases the object at the desired location. The present invention also relates to a corresponding method.

A manipulator is provided. The manipulator includes at least two mechanical fingers. Each of the at least two mechanical fingers includes a first finger segment, a second finger segment, and a third finger segment, a bottom portion of the third finger segment of the respective mechanical finger is movably connected to a top portion of the second finger segment of the respective mechanical finger, and a bottom portion of the second finger segment of the respective mechanical finger is movably connected to a top portion of the first finger segment of the respective mechanical finger. The manipulator further includes a finger driving assembly for each of the at least two mechanical fingers. The finger driving assembly for each of the at least two mechanical fingers includes a plurality of motors that are configured to drive a different one of the finger segments of the respective mechanical finger.

A manipulator is provided. The manipulator includes at least two mechanical fingers. Each of the at least two mechanical fingers includes a first finger segment, a second finger segment, and a third finger segment, a bottom portion of the third finger segment of the respective mechanical finger is movably connected to a top portion of the second finger segment of the respective mechanical finger, and a bottom portion of the second finger segment of the respective mechanical finger is movably connected to a top portion of the first finger segment of the respective mechanical finger. The manipulator further includes a finger driving assembly for each of the at least two mechanical fingers. The finger driving assembly for each of the at least two mechanical fingers includes a plurality of motors that are configured to drive a different one of the finger segments of the respective mechanical finger.

Waveguides, such as light guides, made entirely of elastomeric material or with indents on an outer surface are disclosed. These improved waveguides can be used in sensors, soft robotics, or displays. For example, the waveguides can be used in a strain sensor, a curvature sensor, or a force sensor. In an instance, the waveguide can be used in a hand prosthetic. Sensors that use the disclosed waveguides and methods of manufacturing waveguides also are disclosed.

Waveguides, such as light guides, made entirely of elastomeric material or with indents on an outer surface are disclosed. These improved waveguides can be used in sensors, soft robotics, or displays. For example, the waveguides can be used in a strain sensor, a curvature sensor, or a force sensor. In an instance, the waveguide can be used in a hand prosthetic. Sensors that use the disclosed waveguides and methods of manufacturing waveguides also are disclosed.

The present disclosure generally relates to 3D-architected soft machines with topologically encoded actuation, and methods of making and using the 3D-architected soft machines.

The present disclosure generally relates to 3D-architected soft machines with topologically encoded actuation, and methods of making and using the 3D-architected soft machines.

Various examples are provided related to pneumatic soft robotic spiral grippers. A fiber optic sensor can enable spiral-gripper sensing of, e.g., atwining angle and target cylinder diameter. In one example, a pneumatic soft robotic spiral gripper includes an elastic spine with an embedded fiber optic sensor and a pneumatic spiral channel twining around the elastic spine. The pneumatic spiral channel can be formed in a soft gripping material surrounding the elastic spine. In another example, a method fabrication of a pneumatic soft robotic spiral gripper includes providing a gripper mold with an outer mold wall and a spiral shaped rod positioned within the outer mold wall. An elastic spine can be inserted through the spiral shaped rod and the gripper mold filled with gripping material that can be cured to form a soft gripping material surrounding the elastic spine.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. The systems, methods, apparatuses and computer-readable media instructions described interact with and control robotic systems, in particular pick and place systems using soft robotic actuators to grasp, move and release target objects.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. The systems, methods, apparatuses and computer-readable media instructions described interact with and control robotic systems, in particular pick and place systems using soft robotic actuators to grasp, move and release target objects.