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An energy efficient electrical power generator has a primary energy conversion mechanism, such as an internal combustion engine, and a secondary energy conversion mechanism, such as a thermoelectric device. The secondary energy conversion mechanism increases the electrical power output and efficienc

An energy efficient electrical power generator has a primary energy conversion mechanism, such as an internal combustion engine, and a secondary energy conversion mechanism, such as a thermoelectric device. The secondary energy conversion mechanism increases the electrical power output and efficiency of the generator.

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The invention claimed is: 1. An energy efficient electrical power generator comprising: a primary energy conversion mechanism for generating electrical energy, said primary mechanism being at least 20% efficient at converting its input energy into electrical energy and also rejecting thermal energy

The invention claimed is: 1. An energy efficient electrical power generator comprising: a primary energy conversion mechanism for generating electrical energy, said primary mechanism being at least 20% efficient at converting its input energy into electrical energy and also rejecting thermal energy; a secondary energy conversion mechanism for generating electrical energy through the conversion to electrical energy of at least some of said rejected thermal energy, said secondary energy conversion mechanism being disposed directly on a surface of said primary energy conversion mechanism so that the at least some of said rejected thermal energy is conductively received by said secondary energy conversion mechanism; and a means to combine the electrical energy output of said primary and said secondary energy conversion mechanisms to produce an electrical power generator output at a higher efficiency, when compared with said input energy, than can be done by said primary mechanism alone. 2. The energy efficient electrical power generator of claim 1, wherein said primary energy conversion mechanism is either of an internal combustion engine or a Stirling engine. 3. The energy efficient electrical power generator of claim 1, wherein said secondary energy conversion mechanism is either of a solid state thermoelectric device or a Stirling engine. 4. An energy efficient generator for producing alternating current electrical power comprising: a first electrical power generator that generates electrical energy through the combustion of a fuel, said first electrical power generator comprising: an internal combustion engine that rejects thermal energy; an alternator; a rectifier; and an inverter; a solid state thermoelectric device that generates electrical energy, said thermoelectric device being directly connected to a surface of said engine in a manner that allows conductive heat transfer from said engine to said thermoelectric device; and an electrical circuit through which said electrical energy output from said thermoelectric device is combined with said electrical energy output from said first electrical power generator; wherein the efficiency of conversion to electrical energy of the chemical energy present in said fuel combusted by said internal combustion engine is about 30% to about 100%, when considering the electrical power produced by both of said first electrical power generator and said thermoelectric device. 5. The energy efficient generator of claim 4, wherein said electrical circuit combines DC electrical energy from said rectifier with DC electrical energy from said thermoelectric device. 6. The energy efficient generator of claim 4, wherein said thermoelectric device has a hot side and a cold side, and said hot side of said thermoelectric device is in direct contact with one of an external surface of said engine, an engine block of said engine, a cylinder head of said engine, a coolant-fluid jacket of said engine, or an exhaust manifold of said engine. 7. The energy efficient generator of claim 4, wherein said first generator is a variable speed generator. 8. The energy efficient generator of claim 4 wherein said thermoelectric device is a quantum well thermoelectric device. 9. The energy efficient generator of claim 4 wherein said internal combustion engine operates using any one of diesel fuel, a fuel meeting a “JP” standard, or both. 10. The energy efficient generator of claim 4 wherein said internal combustion engine operates using a bio-fuel. 11. The energy efficient generator of claim 4, which is designed to be transportable. 12. The energy efficient generator of claim 11, which is designed to be man-portable. 13. The energy efficient generator of claim 4, which is capable of producing a sustained output of between about 1 kW and about 10 MW of electrical power. 14. The energy efficient generator of claim 13, which is capable of producing a sustained output of between about 3 kW and about 60 kW of electrical power. 15. The energy efficient generator of claim 4, which produces an alternating current output having a frequency of any one of 50 Hz, 60 Hz, or 400 Hz . 16. The energy efficient generator of claim 1, which is designed to be transportable. 17. The energy efficient generator of claim 16, which is designed to be man-portable. 18. The energy efficient generator of claim 1, which is capable of producing a sustained output of between about 1 kW and about 10 MW of electrical power. 19. The energy efficient generator of claim 18, which is capable of producing a sustained output of between about 3 kW and about 60 kW of electrical power. 20. The energy efficient generator of claim 1, which produces an alternating current output having a frequency of any one of 50 Hz, 60 Hz, or 400 Hz. 21. A method of generating alternating current electrical power comprising the steps of: providing an internal combustion engine powered genset; converting the mechanical energy of said engine into alternating current electrical energy; providing at least one solid state thermoelectric device directly connected to a surface of said engine so that said thermoelectric conductively receives rejected thermal energy from said engine; converting said thermal energy rejected from said engine into electrical energy through said thermoelectric device; and combining said electrical energy from said thermoelectric device with said electrical energy from said engine to produce alternating current electrical power. 22. The method of claim 21 further comprising the step of: storing the electrical energy from said thermoelectric device in a battery; wherein said step of combining includes the use of a buck boost circuit to control electrical energy output from said battery. 23. The method of claim 21 further comprising the step of generating constant frequency alternating current electrical energy from direct current electrical energy, which direct current electrical energy is a combination of direct current electrical energy produced by said thermoelectric device and by said engine.