The present application relates to a stepwise discrete actuator (10) with two shape memory alloy wires (15, 15′) used in an antagonistic configuration to drive a slider (13) that moves a toothed element (12) through tooth-engaging fingers (131, 132) that are spaced at rest by a distance F that is shorter than the distance T between adjacent teeth by an amount sufficient for a stationary finger lifter (14) to lift that of the slider fingers (131, 132) that does not engage the movable toothed element (12) such that it clears the teeth of the latter.

SMA actuators and related methods are described. One embodiment of an actuator includes a base; a plurality of buckle arms; and at least a first shape memory alloy wire coupled with a pair of buckle arms of the plurality of buckle arms. Another embodiment of an actuator includes a base and at least one bimorph actuator including a shape memory alloy material. The bimorph actuator attached to the base.

Shape memory alloy (SMA) actuators and thermal management systems including the same. An SMA actuator includes an SMA lifting tube and a process fluid conduit configured to convey a process fluid through the SMA lifting tube. The SMA actuator assumes a conformation that is based on the temperature of the process fluid. The SMA lifting tube includes a first end and a second end configured to translate relative to the first end at least partially along a lateral direction. A thermal management system is configured to regulate a temperature of a process fluid. The thermal management system includes a heat exchanger that at least partially defines a heat transfer region, a process fluid conduit configured to convey the process fluid through the heat transfer region, and an actuator assembly including the SMA actuator. The actuator assembly is configured to selectively position the heat exchanger within a thermal management fluid flow.

Bistable shape memory alloy inertial actuator capable of preventing accidental actuation caused by environmental temperature variations, its method of operation and its use in devices.

An information handling system display monitor transitions between flat and curved configurations by actuation of a shaped memory alloy wire within the display monitor housing. For example, a nickel titanium wire is heated by application of current across the wire to transition its crystalline form, thereby shortening the wire to adjust the configuration of a foldable display film, such as an OLED display film. Separate shaped memory alloy wires may be used to achieve foldable display film movement in each direction, or actuation of a shaped memory alloy wire in one direction may generate bias in a spring in the opposite direction that is released when a change in foldable display film configuration is desired.

A seating assembly comprises a calf rest coupled to a seat base and having a body that comprises a first trough that extends from a first exterior peak to an interior peak and a second trough that extends from a second exterior peak to the interior peak. The seating assembly also comprises a wire that extends across the first trough from the first exterior peak to the interior peak, the wire being operable between an at rest condition and a contracted condition, wherein movement of the wire from the at rest condition to the contracted condition moves a portion of the wire between the first exterior peak and the interior peak away from a bottom of the first trough. The seating assembly further comprises a controller that prompts electrical current to be supplied to the wire to move the wire from the at rest condition to the contracted condition.

An actuator assembly comprises: first (20) and second (10) parts, wherein a primary axis (P) is defined with reference to the second part; a plurality of lengths of shape-memory alloy wire (30) connected between the first and second parts, wherein the lengths of wire are configured, when selectively powered, to cause three-dimensional movement of the first part relative to the second part; and a mechanism configured, when the lengths of wire are unpowered, to hold the first part in at least one position and/or orientation relative to the second part against the force of gravity for any orientation of the second part.

A seating assembly comprises a calf rest coupled to a seat base and having a body that comprises a first trough that extends from a first exterior peak to an interior peak and a second trough that extends from a second exterior peak to the interior peak. The seating assembly also comprises a wire that extends across the first trough from the first exterior peak to the interior peak, the wire being operable between an at rest condition and a contracted condition, wherein movement of the wire from the at rest condition to the contracted condition moves a portion of the wire between the first exterior peak and the interior peak away from a bottom of the first trough. The seating assembly further comprises a controller that prompts electrical current to be supplied to the wire to move the wire from the at rest condition to the contracted condition.

An activation assembly for a sealed container includes a striker, a detent, and a shape memory alloy (SMA) wire connected to the detent. The SMA wire may move the detent from a first position to a second position relative to the striker based on activation of the SMA wire where, in the first position, the detent is engaged with the striker, and, in the second position, the detent is disengaged from the striker and the striker is movable from a stowed position to a deployed position.

An actuation apparatus comprising: a support structure; a movable element; a helical bearing arrangement supporting the movable element on the support structure and arranged to guide helical movement of the movable element with respect to the support structure along a helical path around a helical axis; an actuating mechanism configured to drive rotation of the movable element around the helical axis which the helical bearing arrangement converts into said helical movement; and a loading arrangement configured to exert a biasing force on the movable element in a direction that is at least substantially normal to the helical path over an operating range of the helical movement.