A soft robotic device with one or more sensors is described. The sensor may be embedded in the soft body of the soft robotic device, attached to the soft body of the soft robotic device, or otherwise linked to the soft body of the soft robotic device.

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.

[Object] To provide a hybrid actuator attaining both driving force and responsiveness, capable of reducing inertia of a movable portion.

[Solution] A pneumatic air muscle has a cylinder (112) provided in a flexible member (100) forming a pneumatic artificial muscle. At the center of an upper lid element (109) of the cylinder, a through hole is opened, and an inner wire (103) of a Bowden cable passes through this through hole and is coupled by means of a spring (106) to a bottom portion of the cylinder. When the pneumatic artificial muscle contracts, the inner wire (103) and the pneumatic air muscle move together because of the stopper (105), and the contraction force is transmitted. In contrast, when the pneumatic air muscle extends, the stopper (105) is disengaged, while the tension of inner wire (103) is kept by the spring (106) to prevent slacking.

[Object] To provide a hybrid actuator attaining both driving force and responsiveness, capable of reducing inertia of a movable portion.

[Solution] A pneumatic air muscle has a cylinder (112) provided in a flexible member (100) forming a pneumatic artificial muscle. At the center of an upper lid element (109) of the cylinder, a through hole is opened, and an inner wire (103) of a Bowden cable passes through this through hole and is coupled by means of a spring (106) to a bottom portion of the cylinder. When the pneumatic artificial muscle contracts, the inner wire (103) and the pneumatic air muscle move together because of the stopper (105), and the contraction force is transmitted. In contrast, when the pneumatic air muscle extends, the stopper (105) is disengaged, while the tension of inner wire (103) is kept by the spring (106) to prevent slacking.

An example robot includes a first hydraulic actuator cylinder connecting a first member to a second member, where the first hydraulic actuator cylinder comprises a first piston and a first chamber. A second hydraulic actuator cylinder connects the first member to the second member, where the second hydraulic actuator cylinder comprises a second piston and a second chamber. A valve system controls hydraulic fluid flow between a hydraulic supply line of pressurized hydraulic fluid, the first and second chambers, and a return line. A controller is configured to determine a gait state of the robot, and based on the determined gait state, provide a signal to the valve system.

An example robot includes a first hydraulic actuator cylinder connecting a first member to a second member, where the first hydraulic actuator cylinder comprises a first piston and a first chamber. A second hydraulic actuator cylinder connects the first member to the second member, where the second hydraulic actuator cylinder comprises a second piston and a second chamber. A valve system controls hydraulic fluid flow between a hydraulic supply line of pressurized hydraulic fluid, the first and second chambers, and a return line. A controller is configured to determine a gait state of the robot, and based on the determined gait state, provide a signal to the valve system.

A gripper head assembly is for a robotic gripping system and includes an actuator. The actuator includes: an actuator body having an attachment region configured to attach the actuator body to the gripper head; a drive element having a mounting section for a tool; a drive having a connector configured to receive an input; the drive being configured to move the drive element upon receiving the input; the drive element defining a through passage; the through passage having a first port for receiving at least one of negative pressure and positive pressure; and, the through passage having an outlet at the mounting section configured to supply the tool with the at least one of negative and positive pressure.

Exemplary embodiments relate to improvements in robotic systems to reduce biological or chemical harborage points on the systems. For example, in exemplary embodiments, robotic actuators, hubs, or entire robotic systems may be configured to allow crevices along joints or near fasteners to be reduced or eliminated, hard corners to be replaced with rounded edges, certain components or harborage points to be eliminated, shapes to be reconfigured to be smoother or flat, and/or or surfaces to be reconfigurable for simpler cleaning.

An autonomous postal delivery systems for conventional mailboxes is disclosed. A self-driving vehicle with LIDAR sensors in conjunction with GPS algorithms guides the mail delivery van safely to predetermined addresses. Onboard optical scanners recognize residential mailboxes and robotic systems retrieve mail from secured compartments and deliver mail efficiently. An objective of the invention is to automate postal deliveries to residential mailboxes using unmanned vehicles.

There is disclosed a rotary actuator apparatus for hydraulically or pneumatically rotating a robotic joint. In an embodiment the apparatus comprises: a curved piston rotatably coupled to an axel shaft, and positioned within a curved piston chamber; resilient barrier modules are adapted to separate the curved piston within the curved piston chamber from first and second hydraulic or pneumatic chambers on either side of the curved piston chamber; whereby, in use, the curved piston is configured to rotate about the axel shaft upon hydraulic or pneumatic pressure being applied to at least one of the first and second hydraulic or pneumatic chambers.