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A power plant configured for converting thermal energy to electricity includes a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from the first temperature. The plant

A power plant configured for converting thermal energy to electricity includes a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from the first temperature. The plant also includes a collector configured for enhancing the temperature difference between the primary and secondary fluids, and a heat engine configured for converting at least some thermal energy to mechanical energy. The heat engine includes a pseudoplastically pre-strained shape-memory alloy disposed in heat exchange relationship with each of the primary and secondary fluids. Further, the plant includes a generator driven by the heat engine and configured for converting mechanical energy to electricity. A method of utilizing a naturally-occurring temperature difference between air and/or water to change a crystallographic phase of the shape-memory alloy to convert the temperature difference into mechanical energy is disclosed.

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1. A power plant configured for converting thermal energy to electricity, the power plant comprising: a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from said first

1. A power plant configured for converting thermal energy to electricity, the power plant comprising: a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from said first temperature;a collector configured for enhancing said temperature difference between said primary fluid and said secondary fluid;a heat engine configured for converting at least some thermal energy to mechanical energy and including a pseudoplastically pre-strained shape-memory alloy disposed in heat exchange relationship with each of said primary fluid and said secondary fluid;a generator configured for converting mechanical energy to electricity and driven by said heat engine;a platform buoyantly disposed in said secondary fluid and configured for supporting at least one of said heat engine, said generator, and said collector for flotation with respect to said secondary fluid; andan intake channel surrounded by said secondary fluid and configured for conveying said secondary fluid to said heat engine. 2. The power plant of claim 1, wherein said intake channel is extendable and retractable with respect to said platform. 3. The power plant of claim 1, wherein said intake channel is insulated from said secondary fluid. 4. The power plant of claim 1, wherein said intake channel further includes a pump configured for conveying said secondary fluid to said heat engine. 5. The power plant of claim 1, wherein capillary action conveys said secondary fluid through said intake channel to said heat engine. 6. The power plant of claim 1, wherein said collector is a solar collector configured for transferring solar energy to said primary fluid. 7. The power plant of claim 2, wherein said intake channel extends with respect to said platform to reach comparatively deeper levels of said secondary fluid. 8. The power plant of claim 2, wherein said intake channel retracts with respect to said platform to reach comparatively shallow levels of said secondary fluid. 9. The power plant of claim 2, wherein said intake channel accesses a depth of said secondary fluid according to a desired temperature difference between said primary fluid and said secondary fluid. 10. The power plant of claim 2, further including a filter disposed at a proximal end of said intake channel and configured for protecting said heat engine from impurities in said secondary fluid. 11. The power plant of claim 3, wherein said secondary fluid is conveyed to said heat engine so that said second temperature is substantially constant. 12. The power plant of claim 3, wherein said intake channel is wrapped in an insulation so that said second temperature is substantially constant along a length of said intake channel. 13. A power plant configured for converting thermal energy to electricity, the power plant comprising: a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from said first temperature;a collector configured for enhancing said temperature difference between said primary fluid and said secondary fluid;a heat engine configured for converting at least some thermal energy to mechanical energy and including a pseudoplastically pre-strained shape-memory alloy disposed in heat exchange relationship with each of said primary fluid and said secondary fluid;a generator configured for converting mechanical energy to electricity and driven by said heat engine;a platform buoyantly disposed in said secondary fluid and configured for supporting at least one of said heat engine, said generator, and said collector for flotation with respect to said secondary fluid; andan intake channel surrounded by said secondary fluid and configured for conveying said secondary fluid to said heat engine, wherein said intake channel is insulated from said secondary fluid, and is extendable and retractable with respect to said platform so that said intake channel accesses a depth of said secondary fluid according to a desired temperature difference between said primary fluid and said secondary fluid. 14. A power plant configured for converting thermal energy to electricity, the power plant comprising: a source of thermal energy provided by a temperature difference between a primary fluid having a first temperature and a secondary fluid having a second temperature that is different from said first temperature;a collector configured for enhancing said temperature difference between said primary fluid and said secondary fluid, wherein said collector is a solar collector and transfers solar energy to said primary fluid;a heat engine configured for converting at least some thermal energy to mechanical energy and including a pseudoplastically pre-strained shape-memory alloy disposed in heat exchange relationship with each of said primary fluid and said secondary fluid;a generator configured for converting mechanical energy to electricity and driven by said heat engine;a platform buoyantly disposed in said secondary fluid and configured for supporting at least one of said heat engine, said generator, and said collector for flotation with respect to said secondary fluid; andan intake channel surrounded by said secondary fluid and configured for conveying said secondary fluid to said heat engine, wherein said intake channel includes a pump configured for conveying said secondary fluid to said heat engine.