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A novel thermal storage device is made up of a plurality of thermal storage canisters. The canisters are in thermal contact with one another so as to form a single thermal storage body. Because the thermal storage device can be broken down into a plurality of discrete thermal storage canisters, it i

A novel thermal storage device is made up of a plurality of thermal storage canisters. The canisters are in thermal contact with one another so as to form a single thermal storage body. Because the thermal storage device can be broken down into a plurality of discrete thermal storage canisters, it is portable and has a high thermal storage capacity. In a particular embodiment, each canister contains a metal phase change material. In a more particular embodiment, the canisters each have a concave region such that when the canisters are assembled the concave regions, together, define a solar receiver.

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1. A thermal energy storage system comprising: a first discrete canister having a wall, said wall of said first discrete canister having an exterior surface and an interior surface, said interior surface of said first discrete canister defining an interior cavity;a second discrete canister having a

1. A thermal energy storage system comprising: a first discrete canister having a wall, said wall of said first discrete canister having an exterior surface and an interior surface, said interior surface of said first discrete canister defining an interior cavity;a second discrete canister having a wall, said wall of said second discrete canister having an exterior surface and an interior surface, said exterior surface of said second discrete canister being in thermal contact with said exterior surface of said first discrete canister, said interior surface of said second discrete canister defining an interior cavity;a thermal storage medium disposed in said interior cavity of said first discrete canister and said interior cavity of said second discrete canister; anda solar light receiving cavity in which solar energy is converted into thermal energy and said thermal energy is transmitted to said thermal storage medium; and whereinsaid first discrete canister and said second discrete canister are free of conduits passing therethrough;a region of said exterior surface of said first discrete canister defines a first part of said solar light receiving cavity, anda region of said exterior surface of said second discrete canister defines a second part of said solar light receiving cavity. 2. The thermal energy storage system of claim 1, further comprising a heat exchanger adapted to facilitate the passage of a heat transfer fluid, to conduct heat from said thermal storage medium to said heat transfer fluid, and to prevent direct physical contact between said heat transfer fluid and said walls of said first discrete canister and said second discrete canister. 3. The thermal energy storage system of claim 1, wherein said region of said exterior surface of said first discrete canister and said region of said exterior surface of said second discrete canister include a concave, ellipsoidal surface. 4. A thermal energy storage system comprising: a first discrete canister having a wall, said wall of said first discrete canister having an exterior surface and an interior surface, said interior surface of said first discrete canister defining an interior cavity;a second discrete canister having a wall, said wall of said second discrete canister having an exterior surface and an interior surface, said exterior surface of said second discrete canister being in thermal contact with said exterior surface of said first discrete canister, said interior surface of said second discrete canister defining an interior cavity; anda thermal storage medium disposed in said interior cavity of said first discrete canister and said interior cavity of said second discrete canister; anda solar light receiving cavity wherein solar energy is converted into thermal energy and said thermal energy is transmitted to said thermal storage medium; and whereineach of said first discrete canister and said second discrete canister are individually removable and are free of conduits passing therethrough;a region of said exterior surface of said first discrete canister defines a first part of said solar light receiving cavity, anda region of said exterior surface of said second discrete canister defines a second part of said solar light receiving cavity. 5. The thermal energy storage system of claim 4, further comprising a heat exchanger adapted to facilitate the passage of a heat transfer fluid, to conduct heat from said thermal storage medium to said heat transfer fluid, and to prevent direct physical contact between said heat transfer fluid and said walls of said first discrete canister and said second discrete canister. 6. The thermal energy storage system of claim 4, wherein said region of said exterior surface of said first discrete canister and said region of said exterior surface of said second discrete canister include a concave, ellipsoidal surface. 7. A thermal energy storage system comprising: a first discrete canister having a wall, said wall of said first discrete canister having an exterior surface and an interior surface, said interior surface of said first discrete canister defining an interior cavity;a second discrete canister having a wall, said wall of said second discrete canister having an exterior surface and an interior surface, said exterior surface of said second discrete canister being in thermal contact with said exterior surface of said first discrete canister, said interior surface of said second discrete canister defining an interior cavity;a thermal storage medium disposed in said interior cavity of said first discrete canister and said interior cavity of said second discrete canister; anda solar light receiving cavity in which solar energy is converted into thermal energy and said thermal energy is transmitted to said thermal storage medium; and whereinsaid first discrete canister and said second discrete canister are free of conduits passing therethrough and are removable, thereby enabling disassembly of said thermal energy storage system, separate transportation of said first discrete canister and said second discrete canister, and reassembly of said thermal energy storage system;a region of said exterior surface of said first discrete canister defines a first part of said solar light receiving cavity, anda region of said exterior surface of said second discrete canister defines a second part of said solar light receiving cavity. 8. The thermal energy storage system of claim 7, wherein said region of said exterior surface of said first discrete canister defining said first part of said solar light receiving cavity includes a concave, ellipsoidal surface; andsaid region of said exterior surface of said second discrete canister defining said second part of said solar light receiving cavity includes a concave, ellipsoidal surface. 9. The thermal energy storage system of claim 7, wherein the melting temperature of said first discrete canister and said second discrete canister is greater than the melting temperature of said thermal storage medium. 10. The thermal energy storage system of claim 9, wherein said thermal storage medium is a phase change material operative to store thermal energy in the form of sensible heat and latent heat. 11. The thermal energy storage system of claim 10, wherein said phase change material is a metal phase change material. 12. The thermal energy storage system of claim 11, wherein said metal phase change material includes aluminum. 13. The thermal energy storage system of claim 12, wherein said first canister and said second canister are constructed from a material that includes silicon carbide. 14. The thermal energy storage system of claim 12, wherein said first canister and said second canister are constructed from a material that includes boron nitride. 15. The thermal energy storage system of claim 12, wherein said first canister and said second canister are constructed from a material that includes Inconel. 16. The thermal energy storage system of claim 7, wherein the volume of said interior cavity of said first canister is greater than the volume of said thermal storage medium disposed in said interior cavity of said first canister when said first canister is heated to a maximum operating temperature of said thermal storage system. 17. The thermal energy storage system of claim 16, further comprising ullage gas disposed in said interior cavity of said first discrete canister and said interior cavity of said second discrete canister. 18. The thermal energy storage system of claim 17, wherein said thermal storage medium is inert to said ullage gas. 19. The thermal energy storage system of claim 7, wherein said interior surface of said first discrete canister and said interior surface of said second discrete canister are impervious to wetting when said thermal storage medium is heated to a liquid state. 20. The thermal energy storage system of claim 19, wherein said interior surface of said first discrete canister and said interior surface of said second discrete canister include an anti-wetting coating operative to make said interior surface of said first canister and said interior surface of said second canister impervious to wetting when said thermal storage medium is heated to a liquid state. 21. The thermal energy storage system of claim 20, wherein said anti-wetting coating includes boron nitride. 22. The thermal energy storage system of claim 19, wherein said first discrete canister and said second discrete canister are formed from a material that is impervious to wetting when said thermal storage medium is heated to a liquid state. 23. The thermal energy storage system of claim 7, further comprising a heat exchanger in thermal contact with said exterior surface of said first discrete canister and said exterior surface of said second discrete canister. 24. The thermal energy storage system of claim 23, wherein said first discrete canister and said second discrete canister are disposed in a perimeter enclosed by said heat exchanger. 25. The thermal energy storage system of claim 7, further comprising: a heat exchanger in thermal contact with said exterior surface of said first discrete canister and said exterior surface of said second discrete canister, said heat exchanger being disposed around said first discrete canister and said second discrete canister;thermal insulation disposed around said heat exchanger;a thermally insulating cover disposed over said solar light receiver, said thermally insulating cover defining an aperture disposed to permit said solar energy to impinge on said solar light receiver; andan opaque plate disposed over said thermally insulating cover and defining an aperture to permit the passage of light therethrough, said aperture of said opaque plate being aligned with said aperture of said thermally insulating cover. 26. The thermal energy storage system of claim 7, wherein: said thermal storage medium is metal phase change material;said thermal energy storage system further includes a ullage gas disposed in said interior cavity of said first discrete canister and in said interior cavity of said second discrete canister, said metal phase change material being inert to said ullage gas;said interior surface of said first discrete canister and said interior surface of said second discrete canister are impervious to wetting by said thermal storage medium when said thermal storage medium is heated to a liquid state; andsaid thermal energy storage system further includes a heat exchanger in thermal contact with said exterior surface of said first canister and said exterior surface of said second canister. 27. The thermal energy storage system of claim 7, further comprising an additional plurality of discrete canisters that, together with said first discrete canister and said second discrete canister, form a single thermal energy storage device. 28. The thermal energy storage system of claim 27, wherein said additional plurality of discrete canisters includes at least four discrete canisters. 29. The thermal energy storage system of claim 27, wherein said exterior surfaces of said walls of said plurality of said discrete canisters directly abut one another. 30. The thermal energy storage system of claim 27, wherein said exterior surfaces of said walls of said plurality of said discrete canisters are at least partially separated by a heat exchange device. 31. The thermal energy storage system of claim 30, wherein each of said plurality of discrete canisters includes a surface that forms a portion of a solar energy receiving feature. 32. The thermal energy storage system of claim 7, further comprising a heat exchanger adapted to facilitate the passage of a heat transfer fluid, to conduct heat from said thermal storage medium to said heat transfer fluid, and to prevent direct physical contact between said heat transfer fluid and said walls of said first discrete canister and said second discrete canister.