Systems, methods, and apparatus for acoustic inspection of a surface are described. An example system may include an inspection robot structured to traverse an inspection surface in a direction of travel. The inspection robot may include a payload having a plurality of arms, connected to the inspection robot, to rotate around respective ones of a plurality of axes while the inspection robot traverses the inspection surface, where each of the plurality of axes is in the direction of travel. A plurality of sleds may be connected to the plurality of arms, and a plurality of inspection sensors connected to the plurality of sleds. The plurality of inspection sensors may be spaced apart from each other at adjustable positions to inspect the inspection surface at an adjustable resolution.

Provided is a multi-joint bending structure body that makes it possible to obtain a structure capable of making a small-radius turn. The present invention comprises: a plurality of first bendable parts 9 and second bendable parts 11 that can elastically bend with respect to the axial direction; and an intermediate part 13 that is positioned between a first bendable part 9 and a second bendable part 11 which are adjacent to each other. The first bendable parts 9 and the second bendable parts 11 are provided with a flexible member 17 that is an integral body in the axial direction. The intermediate part 13 is attached to the flexible member 17 between the first bendable part 9 and the second bendable part 11 which are adjacent, and suppresses the bending of the flexible member 17 with respect to the axial direction.

A finger mechanism includes a first bone member and a second bone member, a first rotation core that rotatably couples the first bone member and the second bone member at end portions in a direction of a length thereof, an extensor tendon that is disposed on a side where the second bone member extends with respect to the first bone member and extends in the direction of the length of the first bone member and the second bone member, a first extensor tendon guide that is provided on both of the first bone member and the second bone member and guides the extensor tendon so that the extensor tendon is in contact with a part of a surface of the first rotation core, an extensor that is connected to the extensor tendon and extends and flexes the extensor tendon, a flex tendon that is disposed on a side where the first bone member flexes with respect to the second bone member and extends in the direction of the length of the first bone member and the second bone member, a first flex tendon guide that is provided on both of the first bone member and the second bone member and guides the flex tendon so that the flex tendon is in contact with another part of the surface of the first rotation core, and a flexor that is connected to the flex tendon and extends and flexes the flex tendon.

A soft bodied robotic member has the appearance of a finger and has a deformable rubber elongated body surrounding an array of rigid ribs interconnected by a perpendicular constraint. The plates form a series of parallel protrusions extending from opposed sides of the body and have a serrated, sawtooth or wavelike appearance. A tether runs through each row of protrusions and draws the corresponding protrusions together in a compressive manner to bend or dispose the finger toward the compressed side. Gaps between the protrusion allow movement of the protrusion towards adjacent protrusions to dispose the body in an arcuate shape. The constraint is a planar sheet that bends with the arc along its width, but resists lateral twisting, thus limiting movement outside a plane defined by the arc and the tether. Multiple finger members may be placed in close geometric proximity for gripping a common object

Welding cable assemblies, welding torch assemblies, and robotic welding systems are disclosed. An example welding-type cable assembly includes: a cable configured to deliver welding-type current and an electrode wire to a welding-type torch, the cable configured to be coupled to the welding-type torch on a first end and coupled to at least one of a wire feeder or a welding-type power supply on a second end; and a spring mechanically coupled to the cable, the spring having a higher resistance to torque than the cable, and the spring configured to transfer a portion of twisting induced at a first end of the cable past a bend portion of the cable.

Compliant manipulators are provided, in which the manipulators include a plurality of slideably interlocked filaments each having a proximate end and a distal end. The interlocked filaments can be formed from a flexible material. The compliant manipulators can also include at least one filament-actuating device operatively connected to the respective distal ends of the plurality of slideably interlocked filaments. The at least one filament-actuating device can be manipulated directly or remotely to push and/or pull the respective filaments to impart a desired movement to the manipulator. The stiffness or flexibility of the manipulators can also be controlled to provide varying degrees of stiffness during use.

A finger mechanism includes a first bone member and a second bone member, a first rotation core that rotatably couples the first bone member and the second bone member at end portions in a direction of a length thereof, an extensor tendon that is disposed on a side where the second bone member extends with respect to the first bone member and extends in the direction of the length of the first bone member and the second bone member, a first extensor tendon guide that is provided on both of the first bone member and the second bone member and guides the extensor tendon so that the extensor tendon is in contact with a part of a surface of the first rotation core, an extensor that is connected to the extensor tendon and extends and flexes the extensor tendon, a flex tendon that is disposed on a side where the first bone member flexes with respect to the second bone member and extends in the direction of the length of the first bone member and the second bone member, a first flex tendon guide that is provided on both of the first bone member and the second bone member and guides the flex tendon so that the flex tendon is in contact with another part of the surface of the first rotation core, and a flexor that is connected to the flex tendon and extends and flexes the flex tendon.

The micro-gripper includes a support (301) to which are articulated fingers (304) and an actuating diaphragm (305), adjusting the spacing of the fingers (304). The support being circular, the fingers (304) may be arranged in any number around it, and the diaphragm (305) delimits a chamber with the support (301) assembled to an equipment (18) for distributing fluids, the pressure of which elastically deforms the diaphragm (305) and controls a simultaneous movement of variations in spacings of the fingers (304).

If the diaphragm is conical and the fingers link up all around, an independence of the movements of the fingers remains, which is invaluable for correctly gripping objects and avoiding excessive efforts.

Application to the gripping of objects, which can be very small and fragile, with a determined and moderate force.

The present invention provides a flexible member having excellent load resistance and flexibility while achieving a reduction in size. This flexible member is provided with: a main body part which includes multiple wave washers that are stacked in an axial direction and are joined to one another by multiple joint parts, and which is capable of bending relative to the axial direction by elastic deformation of the wave washers; and easily deformable parts formed between the joint parts that are adjacent to one another in the circumferential direction in each wave washer.

A deflection element (10) for robot arms has two arm braces that are pivotally mounted on a joint mechanism. In order to create a universally useable deflection element, the two arm braces (12) are each mounted on a support structure (20) of the joint mechanism by means of an arm joint (18), and the two arms braces (12) are coupled to a connecting element (22) between the two arm joints (18), said connecting element (22) being movable relative to the support structure (20); furthermore, at least one actuating element (50; 51), which moves the connecting element (22) and thus pivots the arm braces (12) between the end positions thereof, is arranged between the support structure (20) and the connecting element (22).