Fuel cell comprising a plurality of basic cells connected in series, and method for manufacturing same

The invention claimed is: 1. A fuel cell comprising: a plurality of elementary cells each successively comprising: a first assembly formed by a first current collector and a first electrode, an electrolytic membrane formed by a first polymer material, and a second assembly formed by a second current collector and a second electrode, a plurality of connecting elements configured to connect in series the plurality of elementary cells, a first connecting element of the connecting elements being configured to connect the first assembly of a first elementary cell of the plurality of elementary cells to the second assembly of a second elementary cell of the plurality of elementary cells, the first elementary cell being adjacent to the second elementary cell, wherein: the electrolytic membrane of the first elementary cell has a side wall delineating an empty space with the first connecting element, over a whole thickness of the electrolytic membrane, and a thin barrier layer, formed by a second polymer material, having a water absorption capacity lower than a water absorption capacity of the first polymer material, is interposed between the first connecting element and the electrolytic membrane of the second elementary cell and is in direct contact with the first connecting element and with the electrolytic membrane of the second elementary cell, over a whole thickness of the electrolytic membrane of the second elementary cell. 2. The cell according to claim 1 , wherein each of the connecting elements comprises a first part extending the first current collector of the first assembly of the first elementary cell and a second part connected to the second current collector of the second assembly of the second elementary cell, an inclination angle formed in the counterclockwise direction from the second part of the connecting elements up to the first part of the connecting elements being an obtuse angle. 3. The cell according to claim 2 , wherein the inclination angle is greater than or equal to 135°. 4. The cell according to claim 3 , wherein the inclination angle is greater than or equal to 170°. 5. The cell according to claim 1 , wherein the first elementary cell and second elementary cell are separated by an interconnection area in which there is arranged a stack successively formed by: an external part of the electrolytic membrane of the second elementary cell, the thin barrier layer and one of the connecting elements between the first current collector of the first elementary cell and the second current collector of the second elementary cell. 6. The cell according to claim 5 , wherein the external part of the electrolytic membrane of the second elementary cell presents a cross-section in the form of a right-angled triangle wherein the hypotenuse is in contact with the thin barrier layer itself presenting a cross-section of triangular shape in the same cutting plane. 7. The cell according to claim 1 , wherein the first polymer material comprises hydrophilic functions and in that the second polymer material is formed by the same polymer as the first polymer material, the hydrophilic functions being at least partially deteriorated in the second polymer material. 8. The cell according to claim 7 , wherein the hydrophilic functions are chosen from the —SO 3 , —COOH and —PO(OH) 2 groups. 9. A method for fabricating a fuel cell according to claim 1 , comprising: forming, on a support, the first assemblies of the first and second elementary cells, the first assemblies being separated from one another by empty areas designed to form interconnection areas, forming the electrolytic membranes on the first assemblies of the first and second elementary cells, forming the second assemblies on the electrolytic membranes of the first and second elementary cells, and fabricating the first connecting element in said interconnection areas, wherein forming the electrolytic membranes is performed by forming a continuous thin layer made from a first polymer material on the support, covering the first assemblies and the interconnection areas, and then by at least partial removal of the first polymer material deposited in the interconnection areas, in order to form the empty spaces, and in that it comprises forming the thin barrier layers made from a second polymer material, in the interconnection areas. 10. The method according to claim 9 , wherein removal of the first polymer material in the interconnection areas is a partial removal of said first polymer material performed by a selective etching operation using a plasma. 11. The method according to claim 10 , wherein forming the thin barrier layers is performed after partial removal of the first polymer material in the interconnection areas, by selectively and at least superficially treating the non-removed part of the first polymer material by plasma in the interconnection areas. 12. The method according to claim 10 , wherein forming the thin barrier layers is performed at the same time as partial removal of the first polymer material in the interconnection areas, by plasma treatment.