A hybrid actuation device that includes a first plate coupled to a second plate, a shape memory alloy wire coupled to the first plate, and an artificial muscle positioned between the first plate and the second plate. The artificial muscle includes a housing having an electrode region and an expandable fluid region, a first electrode and a second electrode each disposed in the electrode region of the housing and a dielectric fluid disposed within the housing. The expandable fluid region of the housing is positioned apart from a perimeter of the first plate and the second plate. A first alignment aid is positioned between the first plate and the first electrode, the first alignment aid having an inner surface facing the first plate and an outer surface facing the first electrode.

An actuator that includes a shell, a ring structure within the shell, a shape-memory material wire fixed at opposite points of the ring structure to extend in a first direction across a width of the ring structure, and a cooling fluid provided within the shell and in fluid communication with the shape-memory material wire. When the shape-memory material wire is heated, the shape-memory material wire contracts in the first direction to reduce the width of the ring structure and increases a height of the ring structure extending in a second direction perpendicular to the first direction.

A method of manufacturing an electrode assembly includes positioning a layer stack comprising an electrode positioned between an electrode insulator and a support polymer in a vacuum bag, removing air from the vacuum bag thereby vacuum coupling the electrode to the electrode insulator, and removing the layer stack from the vacuum bag, where upon removal of the layer stack from the vacuum bag, the electrode remains vacuum coupled to the electrode insulator and the electrode insulator is in direct contact with the electrode, thereby forming an electrode assembly.

A method for activating a gas, wherein an electrically conductive aeromaterial having a pore space comprising the gas is electrically contacted and at least one electric current, which varies over time, flows through the aeromaterial, wherein the aeromaterial exhales gas from the pore space when the electrical power consumption is increased and inhales gas from the surroundings of the aeromaterial when the power consumption is decreased, and wherein a temporally pulsed current having predefined pulse power levels, pulse durations and pulse spacings is fed through the aeromaterial and the temperature of the aeromaterial is changed by the time-varying current by 100° C. or more within one second or less. The invention also relates to an electrothermal gas actuator and to uses of a gas actuator.

A hybrid actuation device that includes a first plate coupled to a second plate, a shape memory alloy wire coupled to the first plate, and an artificial muscle positioned between the first plate and the second plate. The artificial muscle includes a housing having an electrode region and an expandable fluid region, a first electrode and a second electrode each disposed in the electrode region of the housing and a dielectric fluid disposed within the housing. The expandable fluid region of the housing is positioned apart from a perimeter of the first plate and the second plate.

A hybrid actuation device includes an artificial muscle, a first plate coupled to a second plate, and a shape memory alloy wire. The artificial muscle includes a housing, a first electrode and a second electrode, and a dielectric fluid. The housing includes a first film layer, a second film layer, an electrode region, and an expandable fluid region. The first electrode and the second electrode are each disposed in the electrode region of the housing. The dielectric fluid is disposed within the housing. The first plate and the second plate are positioned within the housing, the first plate positioned between the first film layer and the first electrode, and the second plate positioned between the second film layer and the second electrode. The shape memory alloy wire extends from the first plate to the second plate and through the dielectric fluid.

An acoustic device may include a housing; an acoustic channel for passing sound through the housing; a valve seat arranged in the acoustic channel; a valve member configured to control the passing of sound through the channel depending on a configuration of the valve member with respect to the valve seat; an actuator comprising a first SMA wire section and a second SMA wire section configured to actuate the valve member and to change a configuration of the valve member with respect to the valve seat from an open configuration to a closed configuration and vice versa, respectively, when activated; and a retention mechanism which is configured to provide a retention force for retaining the valve member in the closed configuration, wherein the retention force is configured to be overcome by the actuator such that the valve member is released from the closed configuration upon activation of the actuator.

A biological engine is configured to transfer mechanical energy from a biological actuator. The biological engine has an enclosure containing a biological feedstock. A cylinder opening is arranged on a bottom side of the enclosure. A turbine hole is arranged on the bottom side of the enclosure. A turbine is arranged in the turbine hole with a turbine seal. A crankshaft assembly has a crankshaft joined to the turbine. A piston is joined to the crankshaft assembly. A cylinder surrounds the piston and connected to the cylinder opening. A biological actuator joins the piston and a cylinder head with an artificial tendon. An electrode pad touches the biological actuator and connected to a current source with a wire and an electrode connector. Electrical current from the current sources causes the biological actuator to expand and contract, moving the piston, turning the crankshaft and transferring the mechanical energy.

The devices and systems described herein generally relate to programmable surfaces. A set of tiles in conjunction with actuators, allow for the surface to be constantly changeable from a first shape to an unlimited variety of second shapes. Once a desired second shape is achieved, the shape can be held by actuating the actuators. The system can include detection and maintenance of the shapes of the programmable surface by controlling which of the actuators are released and when they are released.

A vehicle seat can be configured to provide support to a vehicle occupant in conditions when lateral acceleration is experienced. Shape memory material members can be operatively positioned with respect to a seat portion of the vehicle seat. The shape memory material members can be selectively activated by an activation input. When activated, the shape memory material members can engage a seat pan so as to cause the seat pan to tilt in a respective lateral direction. As a result, a seat cushion supported by the seat pan can also tilt in the respective lateral direction. The seat cushion can be tilted in a lateral direction that is opposite to the direction of the lateral acceleration. Thus, the effects of lateral acceleration felt by a seat occupant can be reduced. The shape memory material members can be selectively activated based on vehicle speed, steering angle, and/or lateral acceleration.