Integrated spring and induction coil for shape-memory alloy (sma) apparatus

1 . An apparatus comprising: a Shape-Memory Alloy (SMA) member configured to transform between a first shape and a second shape based on temperature; and a coil spring that encompasses the SMA member and is mechanically coupled to opposing ends of the SMA member; the coil spring is configured to conduct current from a power source to generate a magnetic field that induces heat in the SMA member, wherein the coil spring is electrically isolated from the SMA member; the coil spring is configured to store mechanical energy as the SMA member transforms from the first shape to the second shape when heated to a transition temperature, and to exert force on the SMA member from the mechanical energy to assist the SMA member in transforming from the second shape to the first shape when cooling below the transition temperature. 2 . The apparatus of claim 1 wherein: the SMA member is configured to twist between the first shape and the second shape based on temperature. 3 . The apparatus of claim 1 wherein: the SMA member is configured to extend and contract between the first shape and the second shape based on temperature. 4 . The apparatus of claim 1 wherein the SMA member comprises: an elongated tube formed from SMA material; a first end fitting coupled to a first end of the elongated tube; and a second end fitting coupled to a second end of the elongated tube. 5 . The apparatus of claim 1 wherein: the coil spring is formed from steel; and a conductive trace is embedded in the coil spring. 6 . The apparatus of claim 5 wherein: the conductive trace is comprised of copper. 7 . The apparatus of claim 1 wherein: the SMA member is comprised of Nickel-Titanium (Ni—Ti). 8 . The apparatus of claim 1 wherein: the SMA member is comprised of Nickel-Titanium-Hafnium (Ni—Ti—Hf). 9 . The apparatus of claim 1 further comprising: a cooling element configured to fit in a hollow portion of the SMA member to cool the SMA member below the transition temperature. 10 . The apparatus of claim 1 wherein: the coil spring is insulated, and includes connectors proximate to opposing ends of the coil spring that are configured to electrically couple the coil spring to the power source. 11 . An actuator comprising: a Shape-Memory Alloy (SMA) member comprising an elongated tube formed from SMA material, and end fittings attached to opposing ends of the elongated tube; and a coil spring that encompasses the elongated tube, wherein opposing ends of the coil spring are mechanically coupled to the end fittings; the coil spring is configured to conduct current from a power source to generate a magnetic field that induces heat in the elongated tube, wherein the coil spring is electrically isolated from the elongated tube; the elongated tube is configured to twist from a first shape to a second shape when heated to a transition temperature; the coil spring is configured to store mechanical energy as the elongated tube twists from the first shape to the second shape; the elongated tube is configured to twist from the second shape to the first shape when cooled below the transition temperature; the coil spring is configured to exert a torsion force on the elongated tube from the mechanical energy to assist the elongated tube in twisting from the second shape to the first shape. 12 . The actuator of claim 11 wherein: the coil spring is formed from steel; and a conductive trace is embedded in the coil spring to form an electrical conductor that extends along the length of the coil spring. 13 . The actuator of claim 12 wherein: the conductive trace is comprised of copper. 14 . The actuator of claim 11 wherein: the elongated tube is comprised of Nickel-Titanium (Ni—Ti). 15 . The actuator of claim 11 further comprising: a cooling element configured to fit in a hollow portion of the elongated tube to cool the elongated tube below the transition temperature. 16 . An actuator comprising: a Shape-Memory Alloy (SMA) member comprising an elongated rod formed from SMA material, and end fittings attached to opposing ends of the elongated rod; and a coil spring that encompasses the elongated rod, wherein opposing ends of the coil spring are mechanically coupled to the end fittings; the coil spring is configured to conduct current from a power source to generate a magnetic field that induces heat in the elongated rod, wherein the coil spring is electrically isolated from the elongated tube; the elongated rod is configured to extend from a first shape to a second shape when heated to a transition temperature; the coil spring is configured to store mechanical energy as the elongated rod extends from the first shape to the second shape; the elongated rod is configured to contract from the second shape to the first shape when cooled below the transition temperature; the coil spring is configured to exert a tension force on the elongated rod from the mechanical energy to assist the elongated rod in contracting from the second shape to the first shape. 17 . The actuator of claim 16 wherein: the coil spring is formed from steel; and a conductive trace is embedded in the coil spring to form an electrical conductor that extends along the length of the coil spring. 18 . The actuator of claim 17 wherein: the conductive trace is comprised of copper. 19 . The actuator of claim 16 wherein: the elongated rod is comprised of Nickel-Titanium (Ni—Ti). 20 . A method of operating an actuator having an elongated tube formed from Shape-Memory Alloy (SMA) material with end fittings attached to opposing ends of the elongated tube, and a coil spring that encompasses the elongated tube with opposing ends of the coil spring mechanically coupled to the end fittings, the method comprising: conducting current through the coil spring to generate a magnetic field that induces heat in the elongated tube, wherein the elongated tube twists from a first shape to a second shape when heated to a transition temperature; storing mechanical energy in the coil spring as the elongated tube twists from the first shape to the second shape, wherein the twisting of the elongated tube of causes a coaxial twisting of the coil spring; removing the current through the coil spring, wherein the elongated tube twists from the second shape to the first shape when cooled below the transition temperature; and exerting a torsion force on the elongated tube from the mechanical energy stored in the coil spring to assist the elongated tube in twisting from the second shape to the first shape. 21 . The method of claim 20 wherein conducting the current through the coil spring comprises: conducting the current through a conductive trace embedded in the coil spring. 22 . The method of claim 20 further comprising: cooling the SMA member below the transition temperature with a cooling element that fits in a hollow portion of the elongated tube.