Shape memory alloy thermostat for subsea equipment

The invention claimed is: 1. A system, comprising: an underwater component; a shape memory alloy thermostat disposed within the underwater component, wherein the shape memory alloy thermostat comprises a plurality of openings configured to expose a shape memory alloy material of the shape memory alloy thermostat to seawater within an interior defined by the underwater component, wherein the shape memory alloy material is configured to undergo a phase change between a first phase and a second phase in response to a temperature change of the seawater, the shape memory alloy material is configured to open or close a fluid path fluidly coupling the interior defined by the underwater component and an environment surrounding an exterior surface of the underwater component in response to the phase change, and wherein the shape memory alloy thermostat comprises a stationary body portion and a movable sleeve portion disposed about an outer surface of the stationary body portion; and an electronics component disposed within the interior of the underwater component, wherein the electronics component is surrounded by the seawater within the interior. 2. The system of claim 1 , wherein the shape memory alloy material is configured to open the fluid path in response to the phase change. 3. The system of claim 1 , wherein the shape memory alloy material is configured to close the fluid path in response to the phase change. 4. The system of claim 1 , wherein the fluid path comprises a water path. 5. The system of claim 1 , wherein the underwater component comprises a thermally insulated enclosure having the interior, an internal component disposed within the interior of the thermally insulated enclosure, and a heat source disposed within the interior. 6. The system of claim 5 , wherein the heat source comprises a fluid conduit, a flow control device, or a combination thereof. 7. The system of claim 1 , wherein the shape memory alloy thermostat comprises a first biasing element made of the shape memory alloy material, wherein the first biasing element is configured to provide a first biasing force in the first phase, the first biasing element is configured to provide a second biasing force in the second phase, and the first and second biasing forces are different from one another. 8. The system of claim 7 , wherein the shape memory alloy thermostat comprises a second biasing element opposing the first biasing element, and the second biasing element is configured to provide a third biasing force greater than the first biasing force and less than the second biasing force. 9. The system of claim 8 , wherein the first and second biasing elements are disposed between the stationary body portion and movable sleeve portion to control movement of the movable sleeve portion relative to the stationary body portion to open or close the fluid path. 10. The system of claim 9 , wherein the stationary body portion comprises a stationary tube, the stationary tube and the movable sleeve portion are concentric with one another, the first biasing element is configured to move the movable sleeve portion in a first direction in the second phase of the shape memory alloy material, and the second biasing element is configured to move the movable sleeve portion in a second direction in the first phase of the shape memory alloy material. 11. The system of claim 10 , wherein the shape memory alloy thermostat comprises a shaft coupled to a first end portion of the movable sleeve portion and extending through a second end portion of the stationary tube, the first biasing element is disposed in a first volume about the shaft inside the movable sleeve portion between, the first and second end portions, and the second biasing element is disposed in a second volume about the shaft inside the stationary tube between the second end portion and a spring retainer coupled to the shaft. 12. The system of claim 11 , wherein the stationary tube comprises the fluid path, and the movable sleeve portion comprises a fluid port into the first volume. 13. The system of claim 1 , wherein the underwater component comprises a subsea component, a mineral extraction component, a flow control device, a controller, a sensor, or a combination thereof. 14. The system of claim 1 , wherein the exterior surface of the underwater component is an entire exterior surface of the underwater component. 15. The system of claim 1 , comprising a fluid conduit extending from an underwater component inlet through the underwater component to an underwater component outlet, wherein the shape memory alloy thermostat is separate from the fluid conduit, and the electronics component is separate from the fluid conduit and external to the fluid conduit. 16. A system, comprising: an underwater container; a fluid conduit extending from an underwater container inlet, through the underwater container, to an underwater container outlet; an underwater component disposed within the underwater container separate from the fluid conduit and external to the fluid conduit; and a shape memory alloy thermostat separate from the fluid conduit, wherein the shape memory alloy thermostat comprises a shape memory alloy material configured to undergo a phase change between a first phase and a second phase in response to a temperature change, the shape memory alloy material is configured to open or close a fluid path fluidly coupling an interior volume formed by the underwater container and an exterior surface of the underwater container in response to the phase change, wherein an interior surface of the underwater container is exposed to the interior volume, and wherein the shape memory alloy thermostat comprises a stationary body portion and a movable sleeve portion disposed about an outer surface of the stationary body portion. 17. The system of claim 16 , wherein the first phase comprises a Martensite phase and the second phase comprises an Austenite phase, and the phase change is configured to occur at a transition temperature. 18. The system of claim 17 , wherein the transition temperature is less than a threshold temperature to protect a material strength of equipment or to protect electronics from overheating. 19. The system of claim 16 , wherein the shape memory alloy thermostat is a subsea equipment thermostat, a mineral extraction equipment thermostat, a flow control device thermostat, or a combination thereof. 20. A system, comprising: a shape memory alloy thermostat, comprising: a first biasing element comprising a shape memory alloy material, wherein the first biasing element is configured to provide a variable first biasing force based on a phase of the shape memory alloy material; a second biasing element configured to provide a second biasing force that opposes the variable first biasing force; a stationary portion comprising a body, wherein the body comprises a plurality of apertures extending from an exterior surface of the body to an interior of the body; a movable valve portion comprising a sleeve, wherein the movable valve portion is configured to open or close depending on whether the variable first biasing force is less than or greater than the second biasing force, and the sleeve is configured to occlude the plurality of apertures of the body to disable fluid flow into the body when the shape memory alloy thermostat is in a closed position; and a rod extending through a surface of the sleeve and into the body, wherein the sleeve is disposed at least partially about the body, the rod is fixedly attached to