Electrical contact thermal sensing system and method

What is claimed is: 1. A thermal sensing system comprising: an electrical contact configured to releasably connect to a mating contact at a mating interface for establishing a conductive path across the mating interface, the electrical contact defining a channel therein that extends from an opening along an outer surface of the electrical contact; a working material within the channel of the electrical contact, the working material having a temperature-dependent expansive property, wherein the working material within the channel is a saturated liquid and vapor mixture that is configured to undergo a phase change from liquid to vapor in response to a temperature within the channel exceeding a designated threshold temperature; a sensing element disposed at least partially outside of the channel and operably connected to the channel through the opening, the working material configured to force the sensing element to undergo a position change relative to the electrical contact in a direction away from the channel based on the temperature within the channel exceeding the designated threshold temperature; and at least one position sensor spaced apart from the electrical contact and configured to detect the position change of the sensing element, indicating that the temperature within the channel exceeds the designated threshold temperature. 2. The thermal sensing system of claim 1 , wherein the electrical contact has a mating end that releasably connects to the mating contact and a mounting end opposite the mating end, wherein the opening of the channel is at the mounting end and the channel extends towards the mating end to a closed end of the channel. 3. The thermal sensing system of claim 1 , wherein the sensing element is a plunger that projects through the opening of the channel, the working material engaging and forcing an interior end of the plunger that is within the channel to move towards the opening in response to the temperature within the channel exceeding the designated threshold temperature. 4. The thermal sensing system of claim 1 , wherein the working material is contained within a tube that has an interior end within the channel of the electrical contact, wherein the tube is mechanically coupled to the sensing element to define a sealed chamber. 5. The thermal sensing system of claim 1 , wherein the working material is contained within a tube that has an interior end within the channel of the electrical contact and an exterior end outside of the channel, the tube also containing a noncondensable gas that represents the sensing element, wherein the at least one position sensor detects the position change of the noncondensable gas by measuring a temperature of the tube at one or more axial locations outside of the channel. 6. A thermal sensing system comprising: an electrical contact configured to releasably connect to a mating contact at a mating interface for establishing a conductive path across the mating interface, the electrical contact defining a channel therein that extends from an opening along an outer surface of the electrical contact; a working material within the channel of the electrical contact, the working material having a temperature-dependent expansive property; a sensing element disposed at least partially outside of the channel and operably connected to the channel through the opening, the working material configured to force the sensing element to undergo a position change relative to the electrical contact based on a temperature within the channel exceeding a designated threshold temperature, wherein sensing element is an expansion tip having one or more side walls configured to expand based on a force exerted by the working material in response to the temperature within the channel exceeding the designated threshold temperature; and at least one position sensor spaced apart from the electrical contact and configured to detect the position change of the sensing element, indicating that the temperature within the channel exceeds the designated threshold temperature. 7. The thermal sensing system of claim 6 , wherein the working material within the channel is a saturated liquid and vapor mixture that is configured to undergo a phase change from liquid to vapor in response to the temperature within the channel exceeding the designated threshold temperature. 8. The thermal sensing system of claim 6 , wherein the working material is a wax that is configured to melt to a liquid phase in response to the temperature within the channel exceeding the designated threshold temperature. 9. The thermal sensing system of claim 6 , wherein the working material within the channel is a saturated liquid and vapor mixture that is configured to undergo a phase change from liquid to vapor in response to the temperature within the channel exceeding the designated threshold temperature. 10. A thermal sensing system comprising: an electrical contact configured to releasably connect to a mating contact at a mating interface for establishing a conductive path across the mating interface, the electrical contact defining a channel therein that extends from an opening along an outer surface of the electrical contact; a working material contained within a tube that has an interior end within the channel of the electrical contact and an exterior end outside of the channel, the working material having a temperature-dependent expansive property; a noncondensable gas contained within the tube, the working material configured to force the noncondensable gas to undergo a position change relative to the electrical contact based on a temperature within the channel exceeding a designated threshold temperature; and at least one position sensor spaced apart from the electrical contact and configured to detect the position change of the noncondensable gas by measuring a temperature of the tube at one or more axial locations outside of the channel. 11. A method comprising: providing an electrical contact that defines a channel therein; and loading a sensing element into the channel of the electrical contact such that an interior segment of the sensing element is within the channel and an exterior segment of the sensing element is outside of the channel, the sensing element comprising one of a bimetallic strip or a shape memory alloy wire, wherein the sensing element is configured to move undergo a position change relative to the electrical contact based on a temperature increase within the channel that exceeds a designated threshold temperature. 12. The method of claim 11 , wherein the sensing element is the bimetallic strip, the bimetallic strip including first and second metal layers that are fixed to one another, the first metal layer having a different coefficient of expansion than the second metal layer such that the exterior segment moves relative to the electrical contact in response to the temperature within the channel exceeding the designated threshold temperature. 13. The method of claim 11 , wherein the sensing element is the shape memory alloy wire, wherein the exterior segment of the shape memory alloy wire is preset to undergo the position change from a first preset position to a second preset position in response to the temperature within the channel exceeding the designated threshold temperature. 14. The method of claim 11 , further comprising: releasably connecting the electrical contact to a mating contact at a mating interface to establish a conductive path for current transfer across the mating interface; and determining that the temperature within the channel exceeds the designated threshold temperature during the current tr