Disclosed is electromechanical actuator for ultrasonic motor in the shape of an n-sided regular polygon plate with n being equal to or greater than five. The polygon plate has two larger main surfaces and at least five smaller side surfaces connecting the main surfaces with each other. Two electrodes are arranged on one of the main surfaces and are electrically isolated from each other by a linear isolation area. One electrode is arranged on the other of the main surfaces. The polygon plate comprises an electromechanical material that undergoes a deformation when electric voltage is applied to the electrodes. The material of the electromechanical actuator comprises a single or polycrystalline piezoelectric ceramic with piezoelectric charge constant d31 differing from piezoelectric charge constant d32 both in sign and in value. The piezoelectric charge constants d31 and d32 define a first and second main deformation direction of the actuator perpendicular to each other. The orientation of the linear isolation area is parallel to either deformation direction.

The invention relates to an annular or hollow cylindrical ultrasonic actuator, on the end faces of which are arranged n≥2 friction elements, and on the outer peripheral surface of which are arranged 2n excitation electrodes, spaced apart from one another in each case by a separating gap, each of the friction elements being arranged in the region of a separating gap, wherein, between friction elements that are adjacent with respect to the periphery of the ultrasonic actuator and are located on different end faces, two excitation electrodes are arranged such that, when the ultrasonic actuator is electrically excited, the friction elements of both end faces simultaneously perform a movement which is suitable for driving an element to be driven to rotate in the same direction. The invention further relates to an ultrasonic motor having an ultrasonic actuator of this kind and having a holding device in which the ultrasonic actuator is inserted.

In a MEMS device in which a first electrode layer, a piezoelectric layer, and a second electrode layer are stacked in this order from a first surface side of a substrate, a first wiring layer is stacked on a second surface on a side opposite to a first surface of the substrate and the first electrode layer and the first wiring layer are connected to each other via a through wiring passing through the substrate.

Provided is a multi-flap standing wave type ultrasonic motor, including a rotor part, a stator part, a control circuit board, and a fixing attachment. The rotor part includes a flange, a rotor ring, and a shaft. The shaft and the flange are joined together by using a first screw and the flange and the rotor ring are joined together by using a second screw. The stator part includes a piezoelectric ceramics, an excitation ring, and flaps. The piezoelectric ceramics and the excitation ring are fixed with glue, the flaps and the excitation ring are connected through welding, and form an angle with the radial direction of the excitation ring. The stator part is sleeved on a support, is attached to a pressure plate and is connected, through an upright, to a locking plate, and to a substrate of the control circuit board to form a fixing attachment. The flaps are an elastomer and a preload provider. The inner diameter of the rotor ring is less than the outer diameter of the flaps. Adopted is a circular-distributed flap structure, an outer rotor design, an integrated design of motor and control, and a sensor, thereby simplifying the system structure. By adopting circular-distributed assembled flaps, the processing difficulty of the flaps is reduced.

An aspect of the present invention relates to a vibration element comprising: a substrate; a ceramic layer containing glass and provided on the substrate; and a piezoelectric element comprising an electrode layer fixed to the substrate with the ceramic layer therebetween and a piezoelectric layer, wherein the piezoelectric layer, the electrode layer, the substrate, and the ceramic layer are integrated by the piezoelectric layer, the electrode layer, the substrate, and the ceramic layer being sintered together at a sintering temperature of from 800° C. or higher to 940° C. or lower.

A method for operating an electromechanical element, comprising the following steps:

by controlling a first control section (A1) which is deformable by an electrical voltage by a first voltage signal (S10) generation of adjusting movements of a friction element which is arranged on the electromechanical element and which is provided for frictional contact with an element (90) to be driven,

controlling of a second control section (A2) which is deformable by an electrical voltage by a second voltage signal (S20), which comprises a signal section (S21), the frequency of which compared to the first voltage signal (S10) is by a factor,

an actor, a drive device with an actor and a motor with a drive device and an element to be driven.

A vibrating device includes a tubular vibrating body and a lens cover coupled to a first surface of the tubular vibrating body. The tubular vibrating body includes a tubular member and piezoelectric vibrators. The lens cover includes a mode changing coupler and a light transmitting body unit disposed in front of a lens of a camera. The mode changing coupler includes a thin portion having a thickness smaller than a thickness of the tubular member.

A vibrating body includes a substrate, a piezoelectric element comprising a piezoelectric layer and electrode layers and joined to the substrate, and a ceramic layer between the substrate and the piezoelectric element. The ceramic layer comprises a first region and a second region which is adjacent to the first region in a direction perpendicular to a thickness direction of the ceramic layer. The first region has a square shape, each side of the first region having a length equal to a thickness of the ceramic layer, the second region has a square shape, each side of the second region having the length equal to the thickness of the ceramic layer, and a difference between a porosity of the first region and a porosity of the second region is not greater than 15%.

A vibration element includes: a substrate; a ceramic layer containing molten glass and provided on the substrate; and a piezoelectric element fixed to the substrate with the ceramic layer therebetween, wherein the piezoelectric element includes a first electrode layer provided in contact with the ceramic layer, a second electrode layer, and a piezoelectric layer provided between the first electrode layer and the second electrode layer, and the first electrode layer has a thickness larger than that of the second electrode layer.

A vibration actuator suppressed in generating abnormal noise while realizing size reduction. The vibration actuator includes a vibration element having a piezoelectric element and an elastic member, and a contact body in contact with the vibration element. The contact body has a direction in which the vibration element and the contact body move relative to each other as a longitudinal direction and a square bar shape substantially uniform in width and thickness in the longitudinal direction, and includes a first section and a second section which are formed with respective R surfaces different in curvature radius on an edge extending in the longitudinal direction, in an area where the contact body performs frictional sliding on the vibration element.