Abstract: A thermoelectric power generation system 20 includes a heat exchanger 1 having double tubes which are an inner tube 1a and an outer tube 1b, and a thermoelectric power generation module 2 mounted between the inner tube and the outer tube. The thermoelectric power generation module generates thermoelectric power using a temperature difference between a medium inside the inner tube and a medium outside the outer tube, and a highly thermal conductive elastic sheet 3a, 3b is mounted between the thermoelectric power generation module and the inner tube and/or the outer tube in close contact therewith.

Abstract: A cold insulation container includes: a cold insulation storage including a coolant vessel; a circulating air fan that causes cold air from the coolant vessel to circulate in the cold insulation storage; a thermoelectric generating module attached to an outer surface of the coolant vessel; and a temperature controller that adjusts a temperature in the cold insulation storage. A temperature difference between the coolant vessel and circulating cold air in the cold insulation storage causes the temperature controller and the circulating air fan to be driven by thermoelectric power generated by the thermoelectric generating module.

Abstract: In a known method in which a cooling pipe that is fixed and rigid is used, variation in a distance from the center of an exhaust heat pipe to the outer surface of a thermoelectric conversion module, variation in the radius of curvature of the curved surface of a cooling pipe, and other factors produce a gap between the outer surface of the thermoelectric conversion module and the inside surface of the cooling pipe. The gap prevents the achievement of desired cooling performance and the improvement of power generation efficiency. A thermoelectric conversion module of the present invention includes two flexible substrates each made of a thin resin film and having mounting lands formed thereon, and a plurality of thermoelectric elements mounted on the mounting lands at high density, wherein one of the two flexible substrate has a plurality of slits to make the module easy to bend.

Abstract: In a known method in which a cooling pipe that is fixed and rigid is used, variation in a distance from the center of an exhaust heat pipe to the outer surface of a thermoelectric conversion module, variation in the radius of curvature of the curved surface of a cooling pipe, and other factors produce a gap between the outer surface of the thermoelectric conversion module and the inside surface of the cooling pipe. The gap prevents the achievement of desired cooling performance and the improvement of power generation efficiency. A thermoelectric conversion module of the present invention includes two flexible substrates each made of a thin resin film and having mounting lands formed thereon, and a plurality of thermoelectric elements mounted on the mounting lands at high density, wherein one of the two flexible substrate has a plurality of slits to make the module easy to bend.