A piezoelectric actuator device, with at least one piezoelectric transducer which has at least one piezoelectric body and an electrode unit assigned to this piezoelectric body, with overall capacitance and including two electrodes lying opposite one another. At least one of the two electrodes of the electrode unit is divided into several individual sub-electrodes, spaced apart from one another and forming with the electrode lying opposite several sub-electrode pairs defining in each case a partial capacitance of the overall capacitance. A separate current-limiting resistor active during charge flow is connected in series to each sub-electrode pair. A valve, for controlling a fluid, is equipped with such an actuator device.

A fluid valve for influencing a fluid flow, including a valve housing in which an actuator is accommodated which can be moved between a first and a second functional position, further including a fluid passage which extends through some regions of the valve housing and terminates at a valve seat in the valve housing, and further including a sealing means which is motion-coupled to the actuator and designed for temporarily sealing the valve seat as a function of the functional position of the actuator, wherein a plastically deformable adjustment means is assigned to and designed to act on the actuator in order to allow a position of the sealing means to be adjusted in at least one of the functional positions of the actuator, the adjustment means being designed as a positionable abutment for the actuator or for a coupling element arranged between the actuator and the sealing means for the purpose of motion-coupling.

A damper assembly includes a housing and rod supported by the housing. A piston assembly is attached to the rod, and is positioned to separate an interior chamber of the housing into a first fluid chamber and a second fluid chamber. The piston assembly includes an annular plate that defines at least one orifice. The orifice interconnects the first fluid chamber and the second fluid chamber in fluid communication. The damper assembly includes a piezoelectric device that is moveable between a disengaged position and an engaged position, in response to a control signal. When disposed in the disengaged position, the piezoelectric device does not affect fluid flow through the at least one orifice. When disposed in the engaged position, the piezoelectric device does affect fluid flow through the at least one orifice, to adjust a damping rate of the piston assembly.

In order to solve the problem of the generation of the interspace between layers, the present invention provides an actuator including: a conductive polymer layer; an ambient temperature molten salt layer; and an opposite electrode layer; wherein the ambient temperature molten salt layer is interposed between the conductive polymer layer and the opposite electrode layer, the ambient temperature molten salt layer includes an adhesive layer in the inside thereof; one surface of the adhesive layer adheres to the conductive polymer layer; and the other surface of the adhesive layer adheres to the opposite electrode layer.

An actuator assembly includes a housing and an actuator arranged within the housing, the actuator including a first part and a second part movable relative to the first part. An insulating material is disposed within the housing, the insulating material encapsulating at least the movable part of the actuator.

A fluid control device includes a first main plate, a second main plate, a driving body, a frame body, a plurality of support bodies, a plurality of gaps, a side wall member, a valve film, and a fixing member. A pump chamber is formed by a flat plate part consisting of the first main plate, the frame body, and the plurality of support bodies, and the second main plate and the side wall member. The valve film is disposed on a main surface of the first main plate on the side where the pump chamber is located. The valve film has an annular shape and fixed to the first main plate by the fixing member so that an outer end thereof is a movable end. The outer end of the valve film overlaps the plurality of gaps located between the plurality of support portions in plan view.

An electrically controlled valve (10) includes a shaft (36), a piezoelectric motor (34) affixed to an end of the shaft (36), a controller (54), a follower (42), a valve member (40), and a valve seat (28). The piezoelectric motor (34) drives the shaft with a first direction and a second opposite direction. The controller (54) provides power to the piezoelectric motor (34) to move the shaft with a first speed and a second speed, the first speed being faster that the second speed. The follower (42) receives the shaft (36), and slides relative to the shaft in response to the shaft moving with the first speed, and grips and moves with the shaft in response to the moving with the second speed and includes a valve member (40). The valve member (40) moves with the follower (42). The valve member (40) is configured to be moved by the follower (42) against the valve seat (28) to restrict fluid flow and to be moved by the follower (42) away from the valve seat to increase the fluid flow.

A method for operating a fluid system, which has a control device with a control functionality and a piezoelectric valve assembly that can be controlled by the control device. The method involves the following steps: providing a target working pressure at the working connection, measurement of the actual working pressure at the working connection by the pressure sensor, transmitting the measurement data to the control device and applying the algorithm to compare the actual working pressure with the target working pressure, activating the at least one integrator to integrate the control deviation of the control voltage (=offset voltage) after the actual working pressure is constant over a certain time period, and changing the control voltage as a function of the determined target/actual deviation taking into account the integrator operation.

A fluid control device includes a first main plate, a second main plate, a driving body, a frame body, a plurality of support bodies, a plurality of gaps, a side wall member, a valve film, and a fixing member. A pump chamber is formed by a flat plate part consisting of the first main plate, the frame body, and the plurality of support bodies, and the second main plate and the side wall member. The valve film is disposed on a main surface of the first main plate on the side where the pump chamber is located. The valve film has an annular shape and fixed to the first main plate by the fixing member so that an outer end thereof is a movable end. The outer end of the valve film overlaps the plurality of gaps located between the plurality of support portions in plan view.

A method for operating a fluid system, which has a control device with a control functionality and a piezoelectric valve assembly that can be controlled by the control device. The method involves the following steps: providing a target working pressure at the working connection, measurement of the actual working pressure at the working connection by the pressure sensor, transmitting the measurement data to the control device and applying the algorithm to compare the actual working pressure with the target working pressure, activating the at least one integrator to integrate the control deviation of the control voltage (=offset voltage) after the actual working pressure is constant over a certain time period, and changing the control voltage as a function of the determined target/actual deviation taking into account the integrator operation.