Breathing apparatus, and method for controlling temperature fluctuations

What is claimed is: 1. A wearable breathing apparatus for controlling temperature of air inhaled by a user, the breathing apparatus comprising: a respiratory conduit that is adapted for the user of the apparatus to inhale and exhale through; and a thermal capacitor operatively connected to the respiratory conduit; wherein the thermal capacitor and the respiratory conduit are adapted such that inhaled air and exhaled air passing through the respiratory conduit also passes through a porous material of the thermal capacitor; wherein the porous material has a time constant, a lumped thermal capacitance of the porous material (mass of the porous material multiplied by specific heat of the porous material) multiplied by a thermal resistance of the porous material (the reciprocal of the heat transfer coefficient multiplied by the surface area available for heat transfer), that is at least 0.5 seconds; wherein the respirator conduit includes one or both of a mask configured to be placed over a mouth and a nose of the user, and a mouthpiece adapted to be placed in the mouth of the user; wherein the thermal capacitor includes a casing, external of the one or both of the mask and the mouthpiece, that surrounds the porous material; wherein the porous material includes one or more of a woven material, a mesh material, a bed of spheres, particles, and/or pellets, and/or a monolith; and wherein the porous material has a void fraction of at least 0.3. 2. The apparatus of claim 1 , wherein the respirator conduit includes the mask. 3. The apparatus of claim 1 , wherein the respirator conduit includes the mouthpiece adapted to be placed in the mouth of the user. 4. The apparatus of claim 1 , wherein the thermal capacitor has a length in a flow direction along which air passes through the thermal capacitor, that is 12.7 cm (5 inches) or less. 5. The apparatus of claim 1 , wherein the porous material includes the woven material and/or the mesh material. 6. The apparatus of claim 5 , wherein the woven and/or mesh material includes a polymer material. 7. The apparatus of claim 1 , wherein the breathing apparatus is unpowered and does not include a cooling fluid. 8. The apparatus of claim 1 , wherein the thermal capacitor has a mass of 0.45 kg or less. 9. The apparatus of claim 1 , wherein the apparatus is part of a rebreather that includes a scrubber in fluid communication with the thermal capacitor, with the scrubber removing at least some of the carbon dioxide from the exhaled air, and the thermal capacitor cooling the inhaled air, at least some of which has passed through the scrubber. 10. A method of cooling breathing air inhaled by a person, the method comprising: passing the air to be inhaled through a porous material of a thermal capacitor, with the porous material cooling the air to be inhaled; and exhaling air through the porous material, thereby cooling the porous material; wherein the porous material has a time constant, a lumped thermal capacitance of the porous material (mass of the porous material multiplied by specific heat of the porous material) multiplied by a thermal resistance of the porous material (the reciprocal of the heat transfer coefficient multiplied by the surface area available for heat transfer), that is at least 0.5 seconds; wherein the porous material includes one or more of a woven material, a mesh material, a bed of spheres, particles, and/or pellets, and/or a monolith; and wherein the porous material has a void fraction of at least 0.3. 11. The method of claim 10 , wherein the cooling the air to be inhaled cools the air from 120° C. or higher, to 48° C. or lower. 12. The method of claim 11 , wherein the thermal capacitor is part of a breathing apparatus that is capable of continuing to cool inhaled air from 120° C. or higher, to 48° C. or lower, for at least 15 minutes; and wherein the inhaling and the exhaling continue to alternate for at least 15 minutes. 13. The method of claim 11 , wherein the porous material is a woven and/or mesh material; and wherein the passing the cooling the air includes passing the air through the mesh material to cool the inhaled air to 48° C. or lower. 14. The method of claim 11 , wherein the porous material is a bed of particles; and wherein the passing the cooling the air includes passing the air through the particles to cool the inhaled air to 48° C. or lower.