Method for high-temperature electrolysis or co-electrolysis, method for producing electricity by means of an SOFC fuel cell, and associated interconnectors, reactors and operating methods

The invention claimed is: 1. A device forming an electrical and fluidic interconnector for a high-temperature electrolysis of steam or for a high-temperature co-electrolysis with carbon dioxide CO2, or an SOFC fuel cell, the device consisting of three metal sheets, extended along two axes of symmetry orthogonal to one another, one of the end metal sheets being intended to come into mechanical contact with the plane of a cathode of an individual electrochemical cell and another of the metal sheets being intended to come into mechanical contact with the plane of an anode of an adjacent individual electrochemical cell, each of the two adjacent individual electrochemical cells of SOEC type being formed of a cathode, of an anode and of an electrolyte inserted between the cathode and the anode, in which device: one of the three metal sheets, referred to as central metal sheet, comprises an embossed central part comprising embossed features defining channels and is pierced, at the periphery of its central part, with at least six ports, the first to fourth ports being extended each over a length corresponding to a portion of the length of the central part along one of the axes X and being distributed in pairs on either side of said axis X, whereas the fifth and sixth ports are extended each over a length corresponding substantially to the length of the central part along the other of the axes Y, one of the end metal sheets, referred to as first end metal sheet, being a flat metal sheet comprising a central part and the first end metal sheet being pierced, at the periphery of its central part, with at least six ports, the first to fourth ports being extended each over a length corresponding to a portion of the length of the central part of the first end metal sheet along one of the axes X and being distributed in pairs on either side of said axis X, whereas the fifth and sixth ports are extended each over a length corresponding substantially to the length of the central part of the first end metal sheet along the other of the axes Y, the central part being pierced with at least two slits extended each over a length corresponding substantially to the length of the central part of the first end metal sheet along the other of the axes Y, the other of the end metal sheets, referred to as second end metal sheet, being a flat metal sheet comprising a hollowed-out central part and is pierced, at the periphery of its central part, with at least six ports, the first to fourth ports being extended each over a length corresponding to a portion of the length of the central part of the second end metal sheet along one of the axes X and being distributed in pairs on either side of said axis X, whereas the fifth and sixth ports are extended each over a length corresponding substantially to the length of the central part of the second end metal sheet along the other of the axes Y, the six ports of the central metal sheet each comprise tongues of steel sheets spaced out from one another, forming a comb, and each comprise slits defined between the edge of one of the ports and a or between two consecutive tongues, the three metal sheets are laminated and assembled together such that: each of the first to sixth ports of one of the three metal sheets is in fluidic communication individually respectively with one of the corresponding first to sixth ports of the other two metal sheets, the first port of the central metal sheet is in fluidic communication with the third port of the central metal sheet via the spaces between tongues of the first port, the channels defined by the embossed features and the spaces between tongues of the third port of the central metal sheet, the second port of the central metal sheet is in fluidic communication with the fourth port of the central metal sheet via the spaces between tongues of the second port of the central metal sheet, the interior chamber delimited between the embossed features and the flat central part of the first end metal sheet and the spaces between tongues of the fourth port of the central metal sheet, the fifth and the sixth port of the first end metal sheet are in fluidic communication with one of the slits and respectively the other of the slits of the first end metal sheet via the spaces between tongues of the fifth port and respectively the sixth of the central metal sheet. 2. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein: the first end metal sheet additionally comprises one or more extended third slits over a length corresponding substantially to the length of the central part along the other of the axes Y, the or each third slit being arranged between the other two slits of the first end metal sheet, the three metal sheets are assembled together such that the extended the or each third slit of the first end metal sheet is in fluidic communication with the interior chamber. 3. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein: the central metal sheet additionally comprises one or more extended slits over a length corresponding substantially to the length of the central part along the other Y of the axes, the or each slit being arranged along an embossed channel, the three metal sheets are assembled together such that the or each extended slit of the central metal sheet is in fluidic communication with the interior chamber. 4. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein: the central metal sheet additionally comprises one or more extended slits over a length corresponding substantially to the length of the central part along the other Y of the axes, the or each slit being arranged transversely to the embossed channels, the three metal sheets are assembled together such that the or each extended slit of the central metal sheet is in fluidic communication with the interior chamber. 5. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein the three metal sheets are assembled together by welding or by brazing. 6. The device forming the electrical and fluidic interconnector as claimed in claim 5 , wherein the three metal sheets are assembled together by weld seams close individually around each fluidic communication. 7. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein the three metal sheets are made of ferritic steel comprising approximately 20% of chromium, preferably made of Crofer® 22APU, or FT18TNb, based on nickel of Inconel® 600 or Haynes® type. 8. The device forming the electrical and fluidic interconnector as claimed in in claim 1 , wherein the tongues of the second port of the central metal sheet and the tongues of the fourth port of the central metal sheet comprise embossed features over at least a portion of their length, the embossed features being supported against the peripheral part of the first end metal sheet. 9. The device forming the electrical and fluidic interconnector as claimed in claim 1 , wherein the three metal sheets are pierced at their periphery with additional ports configured for housing fixing rods. 10. An electrolysis or co-electrolysis reactor comprising a stack of individual solid oxide electrochemical cells each formed of a cathode (the like), of an anode and of an electrolyte inserted between the cathode and the anode, and a plurality of electrical and fluidic interconnectors as claimed in claim 1 , each arranged between two adjacent individual cells with the first end metal sheet in electrical contact with the cathode of one of the two individual cells and the embossed features of the central metal sheet with the anode of the other of the two