A vibration-wave motor includes a vibrator, a first holding member configured to hold the vibrator, a second holding member configured to hold the first holding member, a plurality of pressing members arranged around the vibrator and configured to press the vibrator against a contacting member that contacts the vibrator, a movable plate disposed opposite to the vibrator with respect to the contacting member, and a coupling part configured to couple the second holding member and the movable plate with each other. The vibrator and the contacting member move relatively to each other due to a vibration generated by the vibrator. One of the second holding member and the movable plate includes a transmitting part configured to transmit a driving force of the vibration-wave motor to a driven member.

An actuator including a beam configured to support an object to be driven, and a drive source to which a drive signal is input, wherein the drive signal includes a drive waveform in a shape of sawtooth waveform, a rising of the drive waveform in the shape of sawtooth waveform includes a first staircase waveform and a second staircase waveform continuing from the first staircase waveform, the first staircase waveform generates oscillation of a ringing suppressing waveform for suppressing a ringing waveform to be generated in the second staircase waveform, and the object to be driven is driven to swing in a direction of rotating around the predetermined axis by driving the drive source.

A first lever portion includes a first point-of-effort portion, a first fulcrum portion, and a first point-of-load portion. A second lever portion has a second point-of-effort portion, a second fulcrum portion, and a second point-of-load portion. A first point-of-effort portion is located between a first fulcrum portion and a first point-of-load portion in a direction orthogonal to an axis of a stem. A second fulcrum portion is located between a second point-of-effort portion and a second point-of-load portion in the direction orthogonal to the axis. A distance between the second fulcrum portion and the second point-of-load portion is configured longer than a distance between the second fulcrum portion and the second point-of-effort portion. The second point-of-load portion of the second lever portion is displaced toward the stem and moves the stem toward the piezoelectric element by means of displacement of the intermediate member to the second lever portion side.

A method of manufacturing an actuator includes a first electrode layer forming step, a dielectric elastomer layer forming step, and a second electrode layer forming step, and obtains the actuator in which dielectric elastomer layers and electrode layers have been concentrically laminated. In the first electrode layer forming step, an electrode material is provided to an outer circumferential surface of a shaft section to form the electrode layer. In the dielectric elastomer layer forming step, a sheet-like or paste-like dielectric elastomer material is provided to an outer circumferential surface of the electrode layer to form the dielectric elastomer layer. In the second electrode layer forming step, the electrode material is provided to an outer circumferential surface of the dielectric elastomer layer to form the electrode layer.

A method of manufacturing an actuator includes a first electrode layer forming step, a dielectric elastomer layer forming step, and a second electrode layer forming step, and obtains the actuator in which dielectric elastomer layers and electrode layers have been concentrically laminated. In the first electrode layer forming step, an electrode material is provided to an outer circumferential surface of a shaft section to form the electrode layer. In the dielectric elastomer layer forming step, a sheet-like or paste-like dielectric elastomer material is provided to an outer circumferential surface of the electrode layer to form the dielectric elastomer layer. In the second electrode layer forming step, the electrode material is provided to an outer circumferential surface of the dielectric elastomer layer to form the electrode layer.

A micro-displacement amplifying apparatus comprises two sets of asymmetrical amplifying structures; each set of asymmetrical amplifying structure comprises a plurality of asymmetrical amplifying units connected in series by flexible hinges; the asymmetrical amplifying unit is used for amplifying a micro-displacement; the two sets of asymmetrical amplifying structures are in opposite positions and overlap with each other; the input end and output end are coupled to the asymmetrical amplifying unit by a flexible hinge, respectively; the input end is used for inputting the micro-displacement to the asymmetrical amplifying unit, and the output end is used for outputting the amplified displacement; the two contacting input ends are fixed and coupled to each other, and the two contacting output ends are fixed and coupled to each other. The present disclosure further discloses an amplification method of the micro-displacement amplifying apparatus.

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.

A hollow-cylindrical ultrasonic actuator is disclosed a central axis, an inner peripheral surface facing the central axis and an outer peripheral surface facing away from the central axis and spaced apart from the inner peripheral surface, a closed inner contour curve, a closed outer contour curve, at least one electrode, and an electromechanical material provided between opposed electrodes. In a non-actuated state of the ultrasonic actuator, a curvature of the inner contour curve or of an outer contour curve includes at least three mutually spaced-apart local maximum points.

A hollow-cylindrical ultrasonic actuator is disclosed a central axis, an inner peripheral surface facing the central axis and an outer peripheral surface facing away from the central axis and spaced apart from the inner peripheral surface, a closed inner contour curve, a closed outer contour curve, at least one electrode, and an electromechanical material provided between opposed electrodes. In a non-actuated state of the ultrasonic actuator, a curvature of the inner contour curve or of an outer contour curve includes at least three mutually spaced-apart local maximum points.

This drive unit comprises: an ultrasonic motor that converts the oscillation of a piezoelectric element to linear movement; a contact part that contacts a resonating part; a support part that is connected to a moveable part and supports the contact part; and an impelling part which is coupled to the contact part and which impels the contact part toward the resonating part so that the contact part moves in accordance with the resonance of the resonating part and transmits impelling force to the moveable part via the support part.