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.

The heat pump system and method for operating a heat pump system includes a first Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) core that is adapted to convert movement of the core into energy in response to a temperature change. A second Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) core is in fluid communication with the first core and adapted to convert movement of the second core into energy. A third Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) or elastocaloric core is in fluid communication with the first and second cores and adapted to convert movement of the third core into energy. The first core, second core and the third core are arranged in series and a control system provides waste pressure from the first core to the second core and/or third core.

A driving device of a micropump and a microvalve is provided. The driving device comprises a pump driver controlled by a pump controller, a valve driver controlled by a valve controller, a power supply part, a switch part. The pump driver having a first shape memory alloy wire, a micropump of the first shape memory alloy wire, a wiring part arranged in parallel to the first shape memory alloy wire, and a first selector switch that switches between a state where only the first shape memory alloy wire is energizable and a state where the wiring part is energizable. The valve driver having a plurality of second shape memory alloy wires, a plurality of microvalves of second shape memory alloy wires, and a second selector switch that brings into a state where one of the plurality of second shape memory alloy wires is energizable.

A mechanical driver comprising a wedge shaped member operatively coupled to a shape memory alloy such that the shape memory alloy is able to displace the wedge shaped member in an essentially linear direction. The wedge shaped member is in constant contact with a lever arranged so that it can rotate about a fixed pivot point. A piston is arranged such that it is constant contact with the lever at a point between the pivot point of the lever and the contact point between the lever and the wedge shaped member. Return springs are provided to return the piston, lever and wedge shaped member to their respective start positions. Activation of the shape memory alloy displaces the wedge shaped member along its linear direction and this causes the lever to be deflected about its pivot point and the piston to be deflected in an essentially linear direction that is perpendicular to the linear direction of travel of the wedge shaped member.

A pump uses solar energy to heat bimetals and other materials with high expansion coefficients to create movement that is coupled to pistons or impellers resulting in a fluid pumping action. The moving pistons or impellers are used to push salt water (or any fluid) through a membrane for filtration. Furthermore, the mechanical movement, powered by solar energy can be used for a variety of applications including pumps to move liquids or gases.

A driving device of a micropump and a microvalve is provided. The driving device comprises a pump driver controlled by a pump controller, a valve driver controlled by a valve controller, a power supply part, a switch part. The pump driver having a first shape memory alloy wire, a micropump of the first shape memory alloy wire, a wiring part arranged in parallel to the first shape memory alloy wire, and a first selector switch that switches between a state where only the first shape memory alloy wire is energizable and a state where the wiring part is energizable. The valve driver having a plurality of second shape memory alloy wires, a plurality of microvalves of second shape memory alloy wires, and a second selector switch that brings into a state where one of the plurality of second shape memory alloy wires is energizable.

A device for actuating a compressor. The device includes a rocker movable between a first stable state and a second stable state, arranged such that on movement of the rocker a piston in a compressor chamber of variable volume is driven; one or more shape memory alloy (SMA) elements coupled to the rocker, actuatable to change between a first shape and a second shape; at least one temperature control region within which at least one of the shape memory alloy (SMA) elements is arranged, wherein the temperature within the temperature control region is controlled to vary the temperature of the SMA contained therein.

The hydrogen compression system, comprises a source of gaseous hydrogen at a first pressure, and a mixing unit, adapted to mix hydrogen and an additional gaseous component at said first pressure, the additional gaseous component having an average molecular weight higher than hydrogen. A compression unit is adapted to compress a gaseous mixture comprising hydrogen and the additional gaseous component to a second pressure. A separation unit is fluidly coupled to the compression unit and adapted to separate compressed hydrogen from compressed additional gaseous component. An energy recovery arrangement is further provided to recover energy from the expansion of the compressed additional gaseous component from the second pressure to the third pressure. Disclosed is also a method for efficient hydrogen compression.