Semi-passive cooling using hierarchical vasculature

What is claimed is: 1 . A semi-passive cooling system for a component exposed to fluid flow and heat flux, comprising: a body defining an outer surface, a transpirant reservoir, and a hierarchical vasculature extending from the transpirant reservoir and through at least a portion of the outer surface; and a sacrificial transpirant disposed in the transpirant reservoir in a solid phase, wherein the transpirant is configured to transition between the solid phase and a vapor phase over an operating temperature range of the component. 2 . The semi-passive cooling system of claim 1 , wherein the hierarchical vasculature is configured to drive a liquid phase of the transpirant through the hierarchical vasculature by capillary pressure. 3 . The semi-passive cooling system of claim 1 , wherein the hierarchical vasculature is defined by a plurality of branched lumens, wherein the branched lumens define a plurality levels of the hierarchical vasculature, and wherein adjacent levels of the hierarchical vasculature are joined by at least one branch intersection of the branched lumens. 4 . The semi-passive cooling system of claim 3 , wherein the hierarchical vasculature includes at least 3 levels. 5 . The semi-passive cooling system of claim 3 , wherein at least one of the levels of the hierarchical vasculature is defined by inter-grain porosity of a body material. 6 . The semi-passive cooling system of claim 3 , wherein the hierarchical vasculature is defined by at least an innermost level and an outermost level, wherein the innermost level is in fluid communication with the transpirant reservoir, wherein the outermost level intersects the outer surface, and wherein a size differential between the innermost level and the outermost level is in a range between 10 μm and 1000 μm. 7 . The semi-passive cooling system of claim 1 , wherein the hierarchical vasculature is defined by a plurality of branched lumens, and wherein a size of the branched lumens is tapered between the transpirant reservoir and the outer surface so that a capillary pressure of a liquid phase of the transpirant in the hierarchical vasculature increases from the transpirant reservoir to the outer surface. 8 . The semi-passive cooling system of claim 7 , wherein the capillary pressure of the liquid phase of the transpirant has a pressure differential of at least 100 MPa in the hierarchical vasculature. 9 . The semi-passive cooling system of claim 1 , wherein the transpirant is constructed from at least one of a metal, a metal alloy, a polymer, or a glass. 10 . The semi-passive cooling system of claim 9 , wherein the transpirant is at least one of tin, lead, or gold. 11 . The semi-passive cooling system of claim 1 , wherein a liquid phase of the transpirant has a wetting angle in a range between 10° and 80°. 12 . The semi-passive cooling system of claim 1 , wherein the body is constructed from at least one of a metal, a metal alloy, a carbon fiber composite, a ceramic, a ceramic-metal composite, or a polymer. 13 . The semi-passive cooling system of claim 12 , wherein the body is constructed from at least one of steel, titanium, aluminum, nickel alloy, Hastelloy, Inconel, tungsten, niobium, molybdenum, or ultra-high temperature ceramic. 14 . A semi-passive cooling system for a component exposed to a fluid flow and aerodynamic heating, comprising: a body defining an outer surface, a transpirant reservoir, and a hierarchical vasculature extending between the transpirant reservoir and at least a portion of the outer surface, wherein the hierarchical vasculature intersects the outer surface at a plurality of outlets; and a sacrificial transpirant disposed in the transpirant reservoir in a solid phase, wherein the transpirant is configured to transition between the solid phase and a vapor phase over a temperature gradient extending over the hierarchical vasculature caused by the aerodynamic heating, wherein the outlets are located so that a capillary pressure of a liquid phase of the transpirant at the outlets is greater than a fluid pressure exerted on the outer surface by the fluid flow. 15 . The semi-passive cooling system of claim 14 , wherein the hierarchical vasculature is defined by a plurality of branched lumens, wherein the branched lumens define a plurality of levels of the hierarchical vasculature, and wherein adjacent levels are joined by at least one branch intersection of the branched lumens. 16 . The semi-passive cooling system of claim 15 , wherein at least one of the levels of the hierarchical vasculature is defined by inter-grain porosity. 17 . The semi-passive cooling system of claim 15 , wherein the hierarchical vasculature is defined by at least an innermost level and an outermost level, wherein the innermost level is in fluid communication with the transpirant reservoir, and wherein the outermost level intersects the outer surface, and wherein a size differential between the innermost level and the outermost level is in a range between 10 μm and 1000 μm. 18 . The semi-passive cooling system of claim 14 , wherein the hierarchical vasculature is defined by a plurality of branched lumens, wherein a size of the branched lumens is tapered between the transpirant reservoir and the outer surface so that a capillary pressure of a liquid phase of the transpirant in the hierarchical vasculature increases from the transpirant reservoir to the outer surface, and wherein the capillary pressure of the liquid phase of the transpirant has a pressure differential of at least 100 MPa in the hierarchical vasculature. 19 . A method of making a semi-passive cooling system in a component, comprising: forming a body from a first material, the body including a transpirant reservoir and an outer surface, wherein the body defines a hierarchical vasculature extending between the transpirant reservoir and the outer surface, and filling the transpirant reservoir with a sacrificial transpirant in a solid phase, wherein the transpirant is configured to transition between the solid phase and a vapor phase over an operating temperature range of the component. 20 . The method of claim 19 , wherein the body is formed from the first material by at least one of additive manufacturing and a shell-making process.