An articulatable member includes a distal end, a proximal end, an actuation member, and a constraint member. The actuation member extends from the proximal end to the distal end. The actuation member transmits force to bend the articulatable member from a neutral position. The constraint member extends from the proximal end to the distal end. The constraint member may have opposite ends that are fixed to the distal end and the proximal end. In one embodiment, the constraint member follows a helical path along at least a portion of the articulatable member from the proximal end to the distal end. In another embodiment, the actuation member follows a helical path along at least a portion of the articulatable member.

A machining system includes a robot arm for changing a workpiece or inspecting a machined workpiece, and a probe that is attached to a distal end portion of the robot arm via a force sensor, where the robot arm is controlled such that the probe is arranged at a predetermined measurement position in contact with a side surface of a tool holder, where detection values of the force sensor are obtained over a predetermined period of time in a state where a main spindle is performing rotation operation, where an attached state of the tool holder is determined based on the detection values obtained over the predetermined period of time.

A portable programmable machine enhances efficiency and ergonomics associated with conducting otherwise manual operations within confined spaces. A main body supports a programmable telescoping arm configured to extend through an access port to reach a confined space. The arm includes an articulating wrist for holding and manipulating tools for autonomously processing work parts. The machine can also act semi-autonomously to accommodate interventions of an operator for overriding and fine-tuning interaction of a tool with a work part for proper processing of the part. The arm communicates with a computer in the main body for processing numerical data, and the operator may use a reference camera to fine tune any particular process. The machine incorporates multiple processing functions, for example collar swaging, nut running, cleaning, and/or application of sealants, all through an aircraft wing access port. The main body has lockable wheels for securing the main body near the access port.

A fluid powered gripper can include a body, a bore, a first finger, a second finger, and a piston. The body can include a central bore coaxial with a central longitudinal axis of the body. A bore fluid inlet can be fluidly coupleable to the central bore. The first finger can be rotatable about the body. The second finger can oppose the first finger and the second finger can be rotatable about the body. The piston can be disposed in the central bore. The piston can be powered by a fluid to move between a first position and a second position. The first finger and the second finger can be closed in the first position and open in the second position.

A system for positioning and welding a bracket 30 to a mounting surface, such as a vehicle side rail 40, including using a pivoting tool 20 on a moveable arm 10 that allows the bracket 30 to pivot to minimize the gap between the bracket 30 and its intended mounting surface. The pivoting tool 20 secures, positions near the surface, and allows the bracket 30 to pivot for a precise surface match. A welder 50 welds the bracket 30 to the surface with the gap minimized while the bracket 30 is held in the desired position. The pivoting tool 20 is preferably on an adjustable appendage 12 or combination end 60 mounted on a distal end of the arm 10. The flexible tooling does not require the bracket 30 to be forced with substantial pressure against the mounting surface.

The invention relates to a manipulator having a manipulator arm (5) at the one free end (6) of which a manipulator flange (8) is provided on which an end effector (46) having an application device (9) for machining a workpiece (37) is held. The manipulator flange (8) is rotatable about hand axes (20, 21, 22). A first hand axis (20) extends in the direction of the longitudinal axis (18) of the manipulator arm (5), a second hand axis (21) extends transversely to the first hand axis (20) and a third hand axis (22) extends transversely to the second hand axis (21), wherein the hand axes (20, 21, 22) intersect one another in a common intersection point (26). A machining force (33) acting on the application device (9) is diverted into the manipulator arm (5) by way of the end effector (46). So that process forces occurring during a mechanical operation do not lead to an impairment of the machining pose of the manipulator arm (5), provision is made to fix the application device (9) to the manipulator flange (8) at an attachment angle (30) to the first hand axis (20) in such a way that a machining force (33) occurring at the application device (9) is diverted in a direction (31) towards the manipulator arm (5), which direction extends through the intersection region (25) of the hand axes (20, 21, 22).

A hollow rod developable actuator tool including a first link comprising an outer cylinder, a deployment ring including second link comprising a first portion pivotably connected to the first link at a first joint mounted in a first cavity in the wall of the outer cylinder and a third link comprising a second tool portion pivotably connected to the first portion at a second link, and a fourth link comprising an inner cylinder to which the second portion of the deployment ring is also pivotably connected at a third link mounted in a second cavity in the wall of the inner cylinder. When the inner cylinder of the fourth link is rotated in relation to the outer cylinder of the first link the actuator tool transitions from a first state where the deployment ring is stowed within the tool to a second state where the deployment ring is deployed externally.

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.

A robot system capable of separating an adhesive member from a cover material and sticking the adhesive member on an object without a complicated setting. A robot system including a sticking mechanism configured to clamp and stick an adhesive member on an object and a supply mechanism capable of supplying the adhesive member, wherein the sticking mechanism includes a robot hand configured to clamp and release the adhesive member and a robot arm configured to move the robot hand; and the supply mechanism is separate from the sticking mechanism, supplies the adhesive member in a state that the adhesive member is stuck to a cover material, and separates the cover material from the adhesive member.

A lift device includes a lift apparatus and a base assembly. The lift apparatus is configured to raise and lower an implement assembly. The base assembly is configured to support the lift apparatus. The base assembly includes a deployable operator station transitionable between a deployed position and a stowed position. In the deployed position, the deployable operator station is configured to provide a seating and control arrangement for an operator. In the stowed position, the deployable operator station is substantially sealed from an external environment to limit access to the deployable operator station.