Thermoelectric conversion unit, power generation system, and thermoelectric conversion method

1 . A thermoelectric conversion unit comprising: a plurality of pipes through which a first fluid flows; and a sheet-shaped thermoelectric conversion element being wound around each of the pipes, and configured to generate electric power, based on a temperature difference between the first fluid and a second fluid flowing outside the pipe. 2 . The thermoelectric conversion unit according to claim 1 , wherein the thermoelectric conversion element is configured in such a way that current flows in a direction along a circumference of the pipe orthogonal to a magnetization direction or in a longitudinal direction, due to the temperature difference between the first fluid and the second fluid. 3 . The thermoelectric conversion unit according to claim 1 , wherein the thermoelectric conversion element uses a spin Seebeck effect or an anomalous Nernst effect. 4 . The thermoelectric conversion unit according to claim 1 , wherein the second fluid flows in a vicinity of the pipe in such a way as to oppose a flow of the first fluid. 5 . The thermoelectric conversion unit according to claim 1 , further comprising: a branching portion being formed on an inlet side of the first fluid, and configured to branch a main pipe into the plurality of the pipes; and a connecting portion being formed on an outlet side of the first fluid, and configured to connect the plurality of the pipes and the main pipe, wherein the plurality of the pipes are formed to be in parallel with one another, and the thermoelectric conversion unit is wound around the pipe in such a way as to continue on a substantially entire portion between the branching portion and the connecting portion. 6 . The thermoelectric conversion unit according to claim 1 , wherein the thermoelectric conversion element has a gradient in a composition distribution of material in a longitudinal direction of the pipe. 7 . The thermoelectric conversion unit according to claim 6 , wherein the thermoelectric conversion element has material composition in which thermoelectric conversion efficiency is high in a high temperature region on an inlet side of the first fluid, as compared with an outlet side, and has material composition in which thermoelectric conversion efficiency is high in a low temperature region on an outlet side of the first fluid, as compared with the inlet side. 8 . The thermoelectric conversion unit according to claim 1 , wherein the thermoelectric conversion element is wound around each of the pipes in such a way that a direction of generated current becomes alternate between the adjacent thermoelectric conversion elements, and the thermoelectric conversion elements are connected in such a way that current flows in series. 9 . The thermoelectric conversion unit according to claim 8 , wherein current generated in the adjacent thermoelectric conversion elements flows in directions opposite to each other by making magnetization directions of the adjacent thermoelectric conversion elements different from each other. 10 . The thermoelectric conversion unit according to claim 8 , wherein current generated in the adjacent thermoelectric conversion elements flows in directions opposite to each other by making signs of spin Hall angles of the adjacent thermoelectric conversion elements different from each other. 11 . (canceled) 12 . The thermoelectric conversion unit according to claim 1 , wherein the thermoelectric conversion element is wound around each of the plurality of the pipes in such a way that a direction of generated current becomes the same, and the thermoelectric conversion elements wound around the plurality of the pipes are connected in such a way that current flows in parallel. 13 . (canceled) 14 . The thermoelectric conversion unit according to claim 1 , wherein current flows in the thermoelectric conversion element along a circumferential direction of the pipe, and the thermoelectric conversion element further includes an insulation portion on a part of the circumferential direction. 15 . The thermoelectric conversion unit according to claim 1 , wherein the second fluid is a fluid having a high permeability as compared with water. 16 . A power generation system comprising: a main pipe through which a first fluid flows; the thermoelectric conversion unit according to claim 1 ; and a terminal portion for extracting electric power generated in the thermoelectric conversion element, wherein the pipe of the thermoelectric conversion unit is a pipe branched from the main pipe, and the terminal portion outputs current generated in the thermoelectric conversion element due to a temperature difference between the first fluid flowing from the main pipe into the pipe, and the second fluid. 17 . A thermoelectric conversion method comprising: flowing a first fluid through a plurality of pipes; and generating electric power by a sheet-shaped thermoelectric conversion element wound around each of the pipes, based on a temperature difference between the first fluid and a second fluid flowing outside the pipe. 18 . The thermoelectric conversion method according to claim 17 , further comprising: generating current by the thermoelectric conversion element in a direction along a circumference of the pipe or in a length direction, due to the temperature difference between the first fluid and the second fluid. 19 . The thermoelectric conversion method according to claim 17 , further comprising: flowing the second fluid in a vicinity of the pipe in such a way as to oppose a flow of the first fluid. 20 . The thermoelectric conversion method according to claim 17 , further comprising: branching a main pipe into the plurality of the pipes at a branching portion on an inlet side of the first fluid; making the plurality of the pipes in parallel with one another; connecting the plurality of the pipes and the main pipe at a connecting portion on an outlet side of the first fluid; winding the thermoelectric conversion element around the pipe in such a way as to continue on a substantially entire portion between the branching portion and the connecting portion; and connecting the plurality of the pipes and the main pipe on an outlet side of the first fluid. 21 . The thermoelectric conversion method according to claim 17 , wherein the thermoelectric conversion element has a gradient in a composition distribution of material in a longitudinal direction of the pipe. 22 . The thermoelectric conversion method according to claim 21 , wherein the thermoelectric conversion element has material composition in which thermoelectric conversion efficiency is high in a high temperature region on an inlet side of the first fluid, as compared with an outlet side, and has material composition in which thermoelectric conversion efficiency is high in a low temperature region on an outlet side of the first fluid, as compared with the inlet side. 23 . (canceled) 24 . (canceled) 25 . (canceled) 26 . (canceled) 27 . (canceled)