Clamp mounted thermoelectric generator

What is claimed is: 1 . A system, comprising: a clamp that defines a substantially cylindrical aperture; one or more thermoelectric generator (TEG) layers coupled to the clamp and receive heat from the clamp, wherein the TEG layers comprise thermoelectric nanostructures; and one or more heat sinks coupled to the one or more TEG layers that provide cooling to the TEG layers. 2 . The system as in claim 1 , wherein the one or more heat sinks comprise cooling fins. 3 . The system as in claim 2 , wherein the cooling fins comprise aluminum. 4 . The system as in claim 1 , further comprising: one or more thermal insulation layers located between the clamp and the one or more heat sinks. 5 . The system as in claim 1 , wherein the clamp comprises: a crescent shaped upper portion; and a crescent shaped lower portion, wherein the upper and lower portions of the clamp are coupled by opposing hinges. 6 . The system as in claim 1 , further comprising: an exhaust pipe of an engine located within the aperture of the clamp. 7 . The system as in claim 6 , wherein the heat received by the one or more TEG layers is provided by heated exhaust gas within the exhaust pipe. 8 . The system as in claim 1 , further comprising: a plurality of electrically connected TEG clamps, each TEG clamp comprising a clamp, one or more TEG layers, and one or more heat sinks. 9 . The system as in claim 8 , wherein the TEG clamps are coupled to an exhaust pipe of an engine. 10 . The system as in claim 9 , wherein the TEG clamps are coupled to the exhaust pipe between a catalytic converter and a muffler. 11 . A method comprising: coupling one or more thermoelectric generator (TEG) layers to an exhaust pipe of an engine, wherein the TEG layers comprise thermoelectric nanostructures; transferring heat to the one or more TEG layers; providing cooling to the one or more TEG layers; and generating electricity by the one or more TEG layers by converting the transferred heat into electrical energy. 12 . The method as in claim 11 , further comprising: thermally isolating opposing sides of a particular TEG layer via a housing that comprises a thermally insulating material. 13 . The method as in claim 11 , further comprising: using cooling fins to provide the cooling to the one or more TEG layers. 14 . The method as in claim 11 , further comprising: coupling the one or more TEG layers to the exhaust pipe at a location between a catalytic converter and a muffler. 15 . The method as in claim 11 , further comprising: electrically connecting TEG layers that are coupled to the exhaust pipe using different clamps. 16 . The method as in claim 11 , further comprising: transferring the heat to a first side of a particular TEG layer, wherein the first side of the particular TEG layer opposes a second side of the particular TEG layer to which the cooling is provided. 17 . The method as in claim 11 , wherein the one or more TEG layers comprise a silicon-based nanostructure. 18 . An apparatus comprising: means for converting heat from an exhaust pipe into electrical energy; and means for coupling the heat converting means to the exhaust pipe. 19 . The apparatus as in claim 18 , comprising: means for cooling the heat converting means. 20 . The apparatus as in claim 18 , comprising: means for removing the heat converting means from the exhaust pipe.