The disclosure relates to an ultrasonic actuator formed of a plate having a base, a cover surface which is geometrically similar to the base, and a lateral surface which interconnects the base and the cover surface, wherein the plate includes an electromagnetic material. Electrodes for inciting periodic deformations of the plate are arranged on the base of the plate and on the cover surface of the plate opposite the base. The base includes at least two faces which are arranged in parallel with one another and form contact portions of the lateral surface, and the two faces of the base arranged in parallel with one another, together with connecting lines which interconnect the respective end points of the faces arranged in parallel, form a parallelogram inscribed in the base, in which parallelogram an angle different from 90° is enclosed between adjacent faces. A motor having such an ultrasonic actuator is also disclosed.

The present invention relates to a body (2); at least one actuator (3) made of an electro-active polymer material, which changes form depending on the electrical energy so that it triggers the body (2); at least two reinforcers (4) which allow the actuator (3) to change form, are positioned on the actuator (3) such that they remain opposite to each other, and are connected to the actuator (3) by clamping, thus transmitting movement to the body (2).

A pen-shaped input and/or output device and a method for generating a haptic signal are disclosed. In an embodiment a device includes an actuator unit that has a piezoelectric actuator, wherein the device is a pen-shaped input and/or output device, wherein the pen-shaped input and/or output is configured to use the piezoelectric actuator as a sensor, wherein the piezoelectric actuator is configured to generate a voltage as a result of an actuation of the pen-shaped input and/or output device, and wherein the pen-shaped input and/or output device has a second electronics circuit configured to detect the voltage generated by the piezoelectric actuator and store a characteristic value for the voltage generated.

A microfluidic substrate and a manufacture method thereof, and a microfluidic panel are provided. The microfluidic substrate includes a base substrate, an acoustic wave generation device, and a first switching circuit. The acoustic wave generation device is on the base substrate and configured to emit an acoustic wave to drive a liquid droplet to move over the microfluidic substrates, the acoustic wave generation devices includes an acoustic wave driving electrode and an acoustic wave generation layer, the first switching circuit is on the base substrate, and the first switching circuit is electrically connected to the acoustic wave driving electrode and is configured to transmit an acoustic wave driving signal to the acoustic wave driving electrode, and the acoustic wave driving electrode is configured to drive the acoustic wave generation layer to generate the acoustic wave under control of the acoustic wave driving signal.

A module (1) for a display and/or operating device (10), the module (1) comprising a first transparent electrode (3) having a first matrix of a plurality of electrode islands (3a, 3b, 3c); a transparent piezoelectric layer (2) having a first and a second area; a second transparent electrode (4); a transparent substrate (12); and a conductive path arrangement (25) having at least a first conductive path (24a) on the transparent piezoelectric layer (2), wherein the transparent substrate (12) is coated with the second transparent electrode (4) and the second transparent electrode (4) is disposed between the transparent substrate and the transparent piezoelectric layer (2), and the first area is coated with the first transparent electrode and the second area is coated with the second transparent electrode (4); and the electrode islands (3a, 3b, 3c) are arranged electrically insulated from one another on the first area of the transparent piezoelectric material (2), wherein the at least first conductive path (24a) of the conductive path arrangement (25) is electrically connected to at least one of the electrode islands (3a, 3b, 3c), and at least the first conductive path (24a) and/or at least one of the electrode islands (3a, 3b, 3c) has a rough surface structure with a maximum roughness depth of 4 μm.

A method for forming an electroactive device may include (i) depositing a curable material onto a primary electrode, (ii) curing the deposited curable material to form an electroactive polymer element comprising a cured elastomer material, and (iii) depositing an electrically conductive material onto a surface of the electroactive polymer element opposite the primary electrode to form a secondary electrode. The cured elastomer material may have a Poisson's ratio of between approximately 0.1 and approximately 0.35. Various other devices, methods, and systems are also disclosed.

A piezoelectric actuator includes a piezoelectric element layered in a pillar shape, and electrode plates located on side surfaces of the piezoelectric element and electrically connected to internal electrode layers of the piezoelectric element. Each of the electrode plates includes a body portion extending in a layering direction of the piezoelectric element and a lead portion that extends in a direction intersecting the layering direction and is electrically connected to a lead terminal. The lead portion includes, in at least one side portion, a recessed portion recessed in a width direction of the lead portion.

A display device includes a display panel, a touch sensing layer which is disposed on a first surface of the display panel and senses a touch input of a user, a first vibration device which is disposed on a second surface of the display panel and generates vibration according to driving voltages. The first vibration device generates a first vibration in response to a first touch input of the user to provide a first haptic feedback.

A cooling system employs at least one composite elastocaloric device. Each composite device has a first member with a first material and a second member with an elastocaloric material. The first material increases in size in response to an applied electric or magnetic field and returns to its prior size upon removal of the applied electric or magnetic field. The first and second members are mechanically coupled together such that the increase in size of the first material applies a stress to the elastocaloric material and the return of the first material to its prior size releases said stress, thereby causing the elastocaloric material to absorb heat.

Certain examples disclose and describe apparatus and methods to provide fast response active clearance system with piezoelectric actuator in axial, axial/radial combined, and circumferential directions. In some examples, an apparatus includes an actuator to control clearance between a blade and at least one of a shroud or a hanger, the actuator including a multilayer stack of material, and wherein the actuator is outside a case. The apparatus further includes a rod coupled to the actuator and the at least one of the shroud or the hanger through an opening in the case, the rod to move the at least one of the shroud or the hanger in a radial direction based on axial movement of the multilayer stack of material.