Thermal compensated pressure relief valve using shape memory materials for high temperature application

The invention claimed is: 1 . A pressure relief valve (PRV) comprising an inlet and an outlet defining a fluid flow path therebetween; a plunger, the plunger being moveable between a closed position and an open position, wherein, in the closed position, the plunger blocks the fluid flow path, and, in the open position, fluid may flow through the fluid flow path, the plunger being configured such that pressure at the inlet applies an opening force on the plunger, urging the plunger towards the open position; a biasing means configured to apply a biasing force to the plunger, thereby biasing the plunger towards the closed position such that, when the biasing force is greater than the opening force, the plunger remains in the closed position, and when the opening force is greater than the biasing force and the plunger moves to the open position; and a variable preload means, the variable preload means configured to apply a preload to the biasing means so as to increase the biasing force; wherein the variable preload means comprises a shape memory material such that, above a transition temperature of the shape memory material, the variable preload means is configured to change shape so as to apply a higher preload to the biasing means. 2 . The PRV of claim 1 , wherein the biasing means comprises a spring. 3 . The PRV of claim 2 , further comprising a retaining means configured to retain the spring. 4 . The PRV of claim 3 , wherein the retaining means comprises a bush and nut. 5 . The PRV of claim 1 , wherein the variable preload means is configured to elongate above the threshold temperature, thereby applying a higher preload to the biasing means. 6 . The PRV of claim 5 , wherein the variable preload means comprises a washer. 7 . The PRV of claim 1 , where the PRV is a PRV for use in high temperature pneumatic applications for aircraft engines and/or nacelles. 8 . The PRV of claim 1 , wherein the shape memory material comprises a Nickel/Titanium, nitinol, alloy. 9 . The PRV of claim 8 , wherein the shape memory material comprises at least one of: Ni 49.9/Ti 50.1, Ni 49.0/Ti 51, and Ni 48.0/Ti 52. 10 . The PRV of claim 8 , wherein the shape memory material has a transition temperature of 190° C. 11 . The PRV of claim 1 , wherein, in the closed position, the plunger is configured to seal against an inlet seat, thereby closing the fluid flow path. 12 . The PRV of claim 1 , further comprising: a plunger support, wherein the biasing means is configured to bias against the plunger support. 13 . A system comprising: a duct, and a PRV as claimed in claim 1 , wherein the inlet is in fluid communication with the duct, such that when the pressure in the duct increases above a threshold pressure, the plunger is configured to move to the open position, thereby allowing fluid flow through the fluid flow path, releasing pressure within the duct. 14 . A system comprising: an anti-ice valve, and a PRV as recited in claim 1 ; wherein the inlet is in fluid communication with the AIV such that the PRV is configured to provide pressure regulation to the AIV. 15 . A method of operating a pressure relief valve (PRV), the method comprising providing a fluid to an inlet of the PRV, wherein the pressure of the fluid at the inlet applies an opening force to a plunger urging the plunger from a closed position, where fluid flow through the PRV is blocked, towards an open position, where fluid may flow through the PRV; applying a biasing force to the plunger via a biasing means of the PRV, the biasing means biasing the plunger towards the closed position; and applying a preload to the biasing means of the PRV via a variable preload means comprising a shape memory material thereby increasing the biasing force, wherein, when the temperature of the preload means increases above the transition temperature of the shape memory material, the shape of the preload means changes, thereby increasing the amount of preload on the biasing means.