A MEMS manipulation device has first and second manipulation arms carrying respective mutually facing gripping elements. At least the first manipulation arm is formed by a driving arm and by an articulated arm hinged together through an articulation structure. The first driving arm includes a first beam element and a first piezoelectric region on the first beam element. The first articulation structure includes a first connecting element not deformable in the thickness direction, as well as a first hinge structure interposed between the first driving arm, the first articulated arm, and the first connecting element.

A continuum robot having at least two independently manipulateable bendable section for advancing the robot through a passage, without contacting fragile elements within the passage, wherein the robot incorporates control algorithms that enable the continuum robot to operate and advance into the passage, as well as the systems and procedures associated with the continuum robot and said functionality.

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.

A robotic leg includes a hip, a first pulley attached to the hip and defining a first axis of rotation, a first leg portion having a first end portion and a second end portion, a second pulley rotatably coupled to the second end portion of the first leg portion and defining a second axis of rotation, a second leg portion having a first end portion and a second end portion, and a timing belt trained about the first pulley and the second pulley for synchronizing rotation of the first leg portion about the first axis of rotation and rotation of the second leg portion about the second axis of rotation. The first end portion of the first leg portion is rotatably coupled to the hip and configured to rotate about the first axis of rotation. The first end portion of the second leg portion is fixedly attached to the second pulley.

A micro-gripper includes a support to which are articulated fingers and an actuating diaphragm, adjusting the spacing of the fingers. The support being circular, the fingers may be arranged in any number around it, and the diaphragm delimits a chamber with the support assembled to an equipment for distributing fluids, the pressure of which elastically deforms the diaphragm and controls a simultaneous movement of variations in spacings of the fingers. If the diaphragm is conical and the fingers link up all around, an independence of the movements of the fingers remains.

A gripping device includes a body defining a constraint opening. A gripping member is engaged to the body and is configured to grasp a container. The gripping member includes deformable gripping elements arranged in correspondence of the constraint opening and configured to embrace, when the gripping device is in use, a respective portion of the container. The gripping elements are configured to form an inner gripping space. The gripping member is configured to operate at least between a rest configuration and a gripping configuration wherein the deformable gripping elements are deformed and retain, when the gripping device is in use and in correspondence of the inner gripping space, a container.

An autonomous mobile robot includes a flexible member including a polymer layer extending along an entire length of the flexible member, and an end portion vertically movable away from a body of the robot. A first portion of a fastening mechanism extends along a first lateral edge of the polymer layer and a second portion of the fastening mechanism extends along a second lateral edge of the polymer layer. The first portion of the fastening mechanism is attached to the second portion of the fastening mechanism and forms a conduit to support the image capture device. The conduit includes an inner surface and an outer surface, and the outer surface of the conduit is at least partially defined by the polymer layer. An image capture device is mounted to an end portion of the flexible member.

A flexible joint includes a plurality of links, a plurality of flexures, and at least one cable which can be tensioned or relaxed to cause a bending about a plurality of axes. The links may include a base link; a last link; and a plurality of intermediate links, coupled together by the flexures such that the plurality of intermediate links, the first link, and the last link form a chain of links having the base link at a first end of the chain and the last link at a second end of the chain and each of the plurality of intermediate links is coupled to two other ones of the plurality of links by two flexures. The cable(s) extend through cable pass-through-holes in the links. The links may comprise disks with sloped faces, and may be rotational offset from another around a longitudinal axis. The flexures may comprise living hinges.

The invention discloses a spatial large-stroke compliant hinge with hybrid structure, which includes a rectangular planar unit for implementing an out-of-plane torsion function and a crossed-shaped planar unit for achieving an in-plane rotation function. The crossed-shaped planar unit is formed by two flexible straight beam thin sheets intersecting into a crossed-shaped structure with an angle, and the rectangular planar unit and the crossed-shaped planar unit are connected through an external connection or an embedded connection. The invention overcomes the problems that existing planar structure compliant hinge can only be equivalent to a large-stroke low pair with single degree of freedom, and existing LEMs compliant mechanism is equivalent to compliant hinge with multiple degrees of freedom and with smaller overall strokes. It has the advantages of simple structure, easy processing, easy analysis and calculation, equivalent large stroke space, and multiple degrees of freedom flexibility.

Movement amplifying actuation device (100) comprising at least two piezoelectric beams (101, 102, 103), one beam (101) being attached at a fixed point (111), and at least one hinge (131, 132) connecting a first beam (101, 102) and a second beam (102, 103) between them. Each hinge comprises: a first flexible portion connected to the first beam, a second flexible portion connected to the second beam, a first rigid portion connecting the first and second flexible portions, a second rigid portion capable of being positioned against a fixed point (112, 113), and third flexible portion connecting the second beam to the second rigid portion at a pivot point of said second beam such that the assembly formed by the second rigid portion and the second beam forms a lever around said pivot point. Said flexible and rigid portions form a single piece.