An object gripping mechanism is provided for use with a robotic arm. A robotic arm and method of manufacturing an object gripping mechanism are also provided. The object gripping mechanism includes an attachment modular configured to connect the object gripping mechanism to the robotic arm. The object gripping mechanism also includes a plurality of retractable arms each pivotably connected with the attachment modular. The object gripping mechanism also includes one or more movement mechanisms collectively configured to pivot the plurality of retractable arms to a desired position. The object gripping mechanism further includes a drive mechanism positioned within each of the plurality of retractable arms and configured to pivot the object engagement feature using a gear and timing belt configuration.

An object gripping mechanism is provided for use with a robotic arm. A robotic arm and method of manufacturing an object gripping mechanism are also provided. The object gripping mechanism includes an attachment modular configured to connect the object gripping mechanism to the robotic arm. The object gripping mechanism also includes a plurality of retractable arms each pivotably connected with the attachment modular. The object gripping mechanism also includes one or more movement mechanisms collectively configured to pivot the plurality of retractable arms to a desired position. The object gripping mechanism further includes a drive mechanism positioned within each of the plurality of retractable arms and configured to pivot the object engagement feature using a gear and timing belt configuration.

A boom arm assembly includes an anchoring portion for attachment to an anchoring surface, and a mounting portion for attachment to an auxiliary electrical device. A telescoping link includes an elongate outer member and an elongate inner member. The outer member has a first distal defining a ball joint which is connected to the anchoring portion or the mounting portion, and the inner member has a second distal end defining a ball joint connected to the anchoring portion or the mounting portion. The inner member telescopes within the internal through bore of the outer member. An internal through bore of the inner member and an internal through bore of the outer member align with each other to allow passage of the flexible elongate supply link from the anchoring portion to the mounting portion. A locking mechanism connects locking relative movement between the inner member and the outer member.

A boom arm assembly includes an anchoring portion for attachment to an anchoring surface, and a mounting portion for attachment to an auxiliary electrical device. A telescoping link includes an elongate outer member and an elongate inner member. The outer member has a first distal defining a ball joint which is connected to the anchoring portion or the mounting portion, and the inner member has a second distal end defining a ball joint connected to the anchoring portion or the mounting portion. The inner member telescopes within the internal through bore of the outer member. An internal through bore of the inner member and an internal through bore of the outer member align with each other to allow passage of the flexible elongate supply link from the anchoring portion to the mounting portion. A locking mechanism connects locking relative movement between the inner member and the outer member.

Systems and methods are disclosed providing a flexible articulable device for accessing deep within tight and arbitrarily shaped channels of a body. The flexible or articulable device may employ two, independent locomotion strategies. These strategies can be combined or independently used. However, both strategies use a segmented approach that employs one or multiple embedded actuation units along the body of the device. The multiple embedded actuation units may be individually controlled, are generally connected serially, and generally uses one of the locomotion strategies. One strategy relates to propulsion while the other strategy relates to shape control.

Systems and methods are disclosed providing a flexible articulable device for accessing deep within tight and arbitrarily shaped channels of a body. The flexible or articulable device may employ two, independent locomotion strategies. These strategies can be combined or independently used. However, both strategies use a segmented approach that employs one or multiple embedded actuation units along the body of the device. The multiple embedded actuation units may be individually controlled, are generally connected serially, and generally uses one of the locomotion strategies. One strategy relates to propulsion while the other strategy relates to shape control.

Manipulator devices are used for computer-assisted tele-operated surgery. In some embodiments, the manipulator devices described herein include an arm with a proximal end that is configured to releasably couple with a set-up structure of a computer-assisted tele-operated surgery system. A first ring is rotatably coupled to a distal end portion the arm and is rotatably driven by a first gear motor within the arm. A second ring that is concentric with the first ring is also rotatably coupled to the distal end portion of the arm. Rotations of the second ring are driven by a second gear motor within the arm. An instrument actuator coupling is pivotably coupled to the second ring. The instrument actuator coupling is configured to releasably couple with a computer-assisted tele-operated surgical instrument actuator, and defines a surgical instrument insertion axis.

Manipulator devices are used for computer-assisted tele-operated surgery. In some embodiments, the manipulator devices described herein include an arm with a proximal end that is configured to releasably couple with a set-up structure of a computer-assisted tele-operated surgery system. A first ring is rotatably coupled to a distal end portion the arm and is rotatably driven by a first gear motor within the arm. A second ring that is concentric with the first ring is also rotatably coupled to the distal end portion of the arm. Rotations of the second ring are driven by a second gear motor within the arm. An instrument actuator coupling is pivotably coupled to the second ring. The instrument actuator coupling is configured to releasably couple with a computer-assisted tele-operated surgical instrument actuator, and defines a surgical instrument insertion axis.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.