Wedge-based heat switch using temperature activated phase transition material

We claim: 1. A wedge-based heat switch, comprising: a plurality of thermally conductive wedge segments aligned on a shaft pinned at one end to one of the wedge segments and extending into a longitudinal bore of a final wedge segment, said wedge segments configured to transmit axial motion of the wedge segments along the shaft into radial displacement of at least one wedge segment to contract or expand the plurality of wedge segments to make or break thermal contact between first and second surfaces to provide a thermally conducting state or a thermally insulating state; one or more springs positioned between the shaft and the final wedge segment and entirely contained within the final wedge segment, said springs configured to store energy through compression or expansion along the shaft to provide a force to produce axial motion of the wedge segments including the final wedge segment along the shaft; and a phase transition material positioned entirely between the shaft and the final wedge segment and entirely contained within the final wedge segment, said phase transition material configured to activate based on a temperature stimulus to release the energy stored in the one or more springs. 2. The wedge-based heat switch of claim 1 , wherein the phase transition material is one of a shape memory alloy (SMA), a controlled melt material, or a temperature-dependent adhesive. 3. The wedge-based heat switch of claim 1 , wherein the phase transition material is configured as a switchable shoulder region on a final wedge segment that acts as a bearing surface and a fastener that threads into the shaft and seats on the switchable shoulder region of the final wedge segment to react a mechanical preload of the fastener, wherein upon activation of the phase transition material the switchable shoulder region adapts such that the bearing surface no longer carries the load, which releases the stored energy producing axial motion of the fastener and wedge segments to contract or expand the plurality of wedge segments. 4. The wedge-based heat switch of claim 3 , wherein the heat switch is configured as a thermally conducting to thermally insulating unidirectional switch, wherein a portion of the mechanical preload serves to overcome a compression of the energy storage element to contract the plurality of wedge segments to make thermal contact between the first and second surfaces and a remaining portion of the mechanical preload creates a contact pressure at the first and second surfaces to establish the thermally conducting state, wherein upon activation of the phase transition material the energy storage element expands to axially expand the wedge segments to break thermal contact and form an airgap to establish the thermally insulating state. 5. The wedge-based heat switch of claim 4 , wherein a plurality of said wedge-based heat switches are positioned in a missile between an airframe and electronics within the airframe, wherein the wedge-based heat switches are positioned between the electronics and an outer skin of the airframe, wherein heating of the airframe during missile flight serves to activate the phase transition material to make or break contact between the first and second surfaces on the electronics and the outer skin of the airframe to provide a thermally conducting state or a thermally insulating state. 6. The wedge-based heat switch of claim 3 , wherein the heat switch is configured as a thermally insulating to thermally conducting unidirectional switch, wherein the mechanical preload extends the energy storage element to store energy, wherein the wedge segments are expanded axially to break thermal contact and form an airgap to establish the thermally insulating state, wherein upon activation of the phase transition material the energy storage element contracts to contract the plurality of wedge segments to make thermal contact between the first and second surfaces and create a contact pressure at the first and second surfaces to establish the thermally conducting state. 7. The wedge-based heat switch of claim 3 , wherein the phase transition material forms a collar around the fastener to define the switchable shoulder region, wherein the fastener seats on collar to react the mechanical preload, upon activation of the phase transition material the collar adapts such that the bearing surface no longer carries the load. 8. The wedge-based heat switch of claim 3 , wherein the fastener includes a detent, wherein the phase transition material forms a spring clip located in the switchable shoulder region of the final wedge segment that locks into the fastener detent to react the mechanical preload, upon activation of the phase transition material the spring clip adapts such that the bearing surface no longer carries the load to disengage the fastener. 9. The wedge-based heat switch of claim 1 , wherein the heat switch is a bi-directional switch including an opposing pair of co-axial springs, at least one of which comprised of the phase transition material, positioned inside the longitudinal bore of the final wedge segment and mechanically affixed between the un-pinned end of the shaft and the final wedge segment, one of which stores energy in compression and one of which stores energy in expansion, wherein said opposing energy storage elements are in equilibrium with said wedge segments expanded axially to form an air gap to define the thermally insulating state, upon activation of the phase transition material the spring that applies axial force acting in a direction that loads the wedge segments becomes dominant to overcome the opposing axial force of the opposing spring and contract the plurality of wedge segments to make thermal contact between the first and second surfaces and create a contact pressure at the first and second surfaces to establish the thermally conducting state. 10. A wedge-based heat switch, comprising: a plurality of thermally conductive wedge segments aligned on a shaft, a switchable shoulder region on a final wedge segment that acts as a bearing surface and a fastener that threads into the shaft and seats on the shoulder region of the final wedge segment to react a mechanical preload of the fastener, said wedge segments configured to transmit axial motion of the wedge segments along the shaft into radial displacement of at least one wedge segment to contract or expand the plurality of wedge segments to make or break thermal contact between first and second surfaces to provide a thermally conducting state or a thermally insulating state; one or more springs positioned between the shaft and the final wedge segment and entirely contained within the final wedge segment, said one or more springs configured to store energy through compression or expansion along the shaft to provide a force to produce axial motion of the wedge segments along the shaft; and a phase transition material positioned entirely between the shaft and the final wedge segment and entirely contained within the final wedge segment, said phase transition material configured to form the switchable shoulder region to passively activate based on a temperature stimulus to release the energy stored in the one or more springs, wherein upon activation of the phase transition material the switchable shoulder region of the final wedge segment adapts such that the bearing surface no longer carries the load, which releases the stored energy producing axial motion of the fastener and wedge segments to contract or expand the plurality of wedge segments. 11. The wedge-based heat switch of claim 10 , wherein the phase transition material is one of a shape memory alloy (SMA), a controlled melt material, or a temperature-dependent adhesive.