A linear detector element includes an outer sheath having a first end and a second end, one or more shape memory responsive elements within the outer sheath and between the first end and the second end and first and second conductive wires passing through at least a portion of the outer sheath and through the one or more shape memory responsive elements. The one more shape memory responsive elements include a shape memory actuator surrounding the first and second conductive wires and that has an expanded size and a contracted size and that is sized and arranged such that when the shape memory actuator is in the contracted state the first and second conductive wires contact one another and when the shape memory actuator is in the expanded state the first and second conductive wires do not contact one another.

A shape-memory alloy actuated switch (SMAAS) is provided that enables the stable switching of two separate circuits. The presently disclosed SMAAS includes a substrate, one or more electrical contacts attached to the substrate for connecting to load circuits, and one or more electrically conductive elements for selectively connecting the one or more electrical contacts. The disclosed SMAAS also includes one or more shape-memory alloy actuators attached to the substrate. The one or more shape-memory alloy actuators are configured to move the one or more electrically conductive elements. The shape-memory alloy actuators are self-heated by passing current through the shape-memory alloy material. The disclosed SMAAS may also include electrical contacts to connect an external control current to the shape-memory alloy material. In some examples, the provided SMAAS includes one or more retention mechanisms to prevent movement of the electrically conductive elements after actuation.

An apparatus includes an electrical switch that includes (i) multiple first electrical contacts and (ii) a second electrical contact configured to bridge the first electrical contacts in order to form at least one electrical connection. The apparatus also includes a shape-memory actuator configured to move the second electrical contact in order to selectively open the electrical switch and break the at least one electrical connection. The shape-memory actuator may be configured to be returned to an original shape and the second electrical contact may be configured to be returned to a bridging position in order to reset the apparatus. The apparatus may further include a shutter member configured to be moved between the first electrical contacts in order to prevent re-bridging of the first electrical contacts and to extend an arc-gap between the first electrical contacts.

An apparatus includes an electrical switch that includes (i) multiple first electrical contacts and (ii) a second electrical contact configured to bridge the first electrical contacts in order to form at least one electrical connection. The apparatus also includes a shape-memory actuator configured to move the second electrical contact in order to selectively open the electrical switch and break the at least one electrical connection. The shape-memory actuator may be configured to be returned to an original shape and the second electrical contact may be configured to be returned to a bridging position in order to reset the apparatus. The apparatus may further include a shutter member configured to be moved between the first electrical contacts in order to prevent re-bridging of the first electrical contacts and to extend an arc-gap between the first electrical contacts.

The object is to provide an actuator that consumes less power.

An actuator comprises: a stator that rotatably supports a plurality of stator rollers; a mover that rotatably supports a mover roller disposed between the stator rollers; and a wire made of a shape memory alloy that is disposed between the stator rollers and the mover roller and has both ends connected to respective two stator terminals provided in the stator.

The present invention is a combination of a shape-memory alloy (SMA) element and a fiber sleeve. The SMA connects at each end to a support element, the support elements being moveable relative to each other. The fiber sleeve comprises an electrically insulating sleeve made of flexible fiber material, and is sized so that the sleeve surrounds at least a portion of the SMA element. When the SMA element is deformed upon heating or cooling, causing the support elements to move relative to each other, the fiber sleeve also deforms and continues to surround the portion of the SMA element, inhibiting the flow of electric current from the SMA element to its surroundings.

The present invention relates to a system and method for or forming an elongated length of SMA or NTE material wire for use in an engine core, said system comprising a heat source adapted to cooperate with a base support; a wire holder support having a cavity to define a mould; said heat source is to configured to receive the wire holder support to engage the base support; the wire holder support holds part of the SMA or NTE material wire in the cavity such that on heating the part of the SMA or NTE material wire causes the SMA or NTE material wire shape to change to match the shape of the cavity mould; and a cooling module configured to cool the wire holder support and the SMA or NTE material wire shape.

The present invention concerns an electric actuator (A, A), comprising a rotor member (6) and an actuating assembly (4) configured to interfere with said rotor member (6), causing it to rotate, characterized in that said rotor member (6) comprises a pair of eccentric reliefs (63) arranged so as to interfere with said actuating assembly (4), and in that said actuating assembly (4) comprises a shape memory wire (2), wherein said actuating assembly (4) is configured to cause the rotation of said rotor member (6) when electric current flows through at least a portion of said shape memory wire (2).

An overcurrent protection device for a circuit to be monitored, includes at least one trigger unit, which is configured for an interruption of the circuit in at least one trigger situation and which comprises at least one conductor section, which is configured for a conduction of a current to be monitored, at least one trigger element, which comprises at least one magnetically and thermally shape-shiftable material and is, in the trigger situation, configured for a thermally-induced and/or magnetically-induced deformation in dependence on a current that flows through the conductor section, and at least one actuation element, which is operatively connected with the trigger element and is configured for a transmission of at least one actuation movement and/or at least one actuation force to at least one interrupter switch.

A power switch device has a housing, a movable shuttle and at least one shape memory alloy actuator. The housing has a cavity and stationary current carrying contacts which extend through the housing to the cavity. The movable shuttle with a bridge contact provided in the cavity. The at least one shape memory alloy actuator is attached to a first end of the shuttle and to a first end of the housing. The at least one shape memory alloy actuator is configured to respond to a first activation signal. The at least one shape memory alloy actuator contracts from an initial shape in response to the first actuation signal to move the shuttle and the bridge contact toward the stationary current carrying contacts to a closed position in which the bridge contact is positioned in electrical engagement with the stationary current carrying contacts.