J. Lemanski, V. Krishnan, R. Manjeri, W. Notardonato, R. Vaidyanathan
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A Low Hysteresis NiTiFe Shape Memory Alloy Based Thermal Conduction Switch
Shape memory alloys possess the ability to return to a preset shape by undergoing a solid state phase transformation at a particular temperature. This work reports on the development and testing of a low temperature thermal conduction switch that incorporates a NiTiFe shape memory element for actuation. The switch was developed to provide a variable conductive pathway between liquid methane and liquid oxygen dewars in order to passively regulate the temperature of methane. The shape memory element in the switch undergoes a rhombohedral or R‐phase transformation that is associated with a small hysteresis (typically 1–2 degrees C) and offers the advantage of precision control over a set temperature range. For the NiTiFe alloy used, its thermomechanical processing, subsequent characterization using dilatometry, differential scanning calorimetry and implementation in the conduction switch configuration are addressed.