초록 ▼

A thermoelectric power generator is disclosed for use to generate electrical power from heat, typically waste heat. An intermediate heat transfer loop forms a part of the system to permit added control and adjustability in the system. This allows the thermoelectric power generator to more effectivel

A thermoelectric power generator is disclosed for use to generate electrical power from heat, typically waste heat. An intermediate heat transfer loop forms a part of the system to permit added control and adjustability in the system. This allows the thermoelectric power generator to more effectively and efficiently generate power in the face of dynamically varying temperatures and heat flux conditions, such as where the heat source is the exhaust of an automobile, or any other heat source with dynamic temperature and heat flux conditions.

대표청구항 ▼

What is claimed is: 1. A thermoelectric power generation system comprising: a thermoelectric generator having thermoelectrics with at least one cold side and at least one hot side configured to generate electrical power when a temperature gradient is present between said at least one cold side and

What is claimed is: 1. A thermoelectric power generation system comprising: a thermoelectric generator having thermoelectrics with at least one cold side and at least one hot side configured to generate electrical power when a temperature gradient is present between said at least one cold side and said at least one hot side; an intermediate heat transfer loop in thermal communication with said at least one hot side and in thermal communication with at least one main heat source, the at least one main heat source having a first working fluid flowing through the at least one main heat source, the intermediate heat transfer loop having a second working fluid flowing through the intermediate heat transfer loop and in thermal communication with said at least one hot side, wherein the intermediate heat transfer loop and the at least one main heat source are not in fluid communication with one another; and a controller in communication with flow control devices in said intermediate heat transfer loop, the controller adapted to control the heat flow in the intermediate heat transfer loop in response to changes in heat originating from the at least one main heat source. 2. The thermoelectric power generation system of claim 1, further comprising a thermal storage. 3. The thermoelectric power generation system of claim 1, further comprising a heat exchanger between the intermediate heat transfer loop and the main heat source, and further comprising a heat exchanger bypass controllable via the controller, to cause some or all of the heat from the main heat source to bypass the heat exchanger. 4. A thermoelectric power generation system for a main heat source, the power generation system comprising: a thermoelectric generator having thermoelectrics with at least one cold side and at least one hot side configured to generate electrical power when a temperature gradient is present across said at least one cold side and said at least one hot side; an intermediate heat transfer loop in thermal communication with said at least one cold side and in communication with at least one heat dissipation device, wherein the heat dissipation device is separate from a main heat source, the main heat source having a first working fluid flowing through the main heat source, the intermediate heat transfer loop having a second working fluid flowing through the intermediate heat transfer loop and in thermal communication with said at least one cold side, wherein the intermediate heat transfer loop and the main heat source are not in fluid communication with one another; and a controller in communication with flow control devices in said intermediate heat transfer loop, the controller adapted to control the heat flow in the intermediate heat transfer loop in response to changes in operating conditions for the thermoelectrics. 5. The thermoelectric power generation system of claim 4, wherein the heat source is an engine, having a main coolant system. 6. The thermoelectric power generation system of claim 5, wherein the intermediate heat transfer loop can be thermally connectable to the main coolant system of the engine, such that during engine warm-up, heat transferred from the thermoelectrics to the intermediate heat transfer loop is further transferred to the main cooling system for the engine, thereby decreasing warm-up time for the engine. 7. The thermoelectric power generation system of claim 4, further comprising a heat exchanger between the intermediate heat transfer loop and the main heat source, and further comprising a heat exchanger bypass controllable via the controller, to cause some or all of the heat from the main heat source to bypass the heat exchanger. 8. A method of generating power from waste heat from a main heat source using a thermoelectric generator having thermoelectrics with at least one cold side and at least one hot side configured to generate electrical power when a temperature gradient is present across said at least one cold side and said at least one hot side, the method comprising the steps of: transferring heat from a first working fluid flowing through the main heat source to a second working fluid flowing through an intermediate heat transfer loop and in thermal communication with said at least one cold side or with said at least one hot side, wherein the intermediate heat transfer loop is not in fluid communication with the main heat source, the intermediate heat transfer loop in thermal communication with a heat dissipation device; and controlling the flow of heat in said intermediate heat transfer loop in response to changes in operating conditions of the main heat source. 9. The method of claim 8, wherein the heat source is an engine, having a main coolant system. 10. The method of claim 9, wherein the intermediate heat transfer loop can be thermally connectable to the main coolant system of the engine, the method further comprising the step of during engine warm-up, transferring heat from the thermoelectrics to the intermediate heat transfer loop and further to the main coolant system for the engine, thereby decreasing warm-up time for the engine. 11. The method of claim 8, further comprising the step of controlling the flow of heat from the main heat source to the intermediate loop based on changing heat flux of the main heat source and the capacity of the thermoelectric generator. 12. The thermoelectric power generation system of claim 1, further comprising a heat exchanger in thermal communication with the intermediate heat transfer loop and in thermal communication with the main heat source. 13. The thermoelectric power generation system of claim 12, further comprising thermal storage. 14. The thermoelectric power generation system of claim 12, further comprising a heat exchanger bypass controllable via the controller to cause some or all of the heat from the main heat source to bypass the heat exchanger. 15. The thermoelectric power generation system of claim 4, wherein the heat source is an engine having a main coolant system. 16. The thermoelectric power generation system of claim 15, wherein the intermediate heat transfer loop is thermally connectable to the main coolant system of the engine, such that during engine warm-up, heat transferred from the thermoelectrics to the intermediate heat transfer loop is further transferred to the main cooling system for the engine, thereby decreasing warm-up time for the engine. 17. The thermoelectric power generation system of claim 4, further comprising a heat exchanger in thermal communication with the intermediate heat transfer loop and in thermal communication with the main heat source. 18. The thermoelectric power generation system of claim 17, further comprising a heat exchanger bypass controllable via the controller to cause some or all of the heat from the main heat source to bypass the heat exchanger. 19. The thermoelectric power generation system of claim 1, wherein the first working fluid and the second working fluid are different from one another. 20. The thermoelectric power generation system of claim 4, wherein the first working fluid and the second working fluid are different from one another. 21. The method of claim 8, wherein the first working fluid and the second working fluid are different from one another.