Reversible individual unit for electrolysis or co-electrolysis of water (SOEC) or for fuel cell (SOFC) with operation under pressure and decoupled compressive force

The invention claimed is: 1. A module, intended to form an individual unit of an electrolysis or co-electrolysis reactor of SOEC type, comprising: an individual electrochemical cell (C 1 ) formed of a cathode, or an anode and of an electrolyte inserted between the cathode and the anode, a first and a second device each forming an electrical and fluid tight interconnector, each consisting of a component made of electron-conducting and gastight material, the first and second interconnectors being arranged on either side of the individual cell; the second interconnector being pierced with a conduit for recovering hydrogen produced, which opens out at a periphery of the cell on a cathode side; the second interconnector being pierced with a conduit for recovering oxygen produced, which opens out at a periphery of the cell on an anode side so as to carry out homogenous distribution of the oxygen produced to a first recovery conduit; a first electrically insulating seal arranged at the periphery of the individual cell and bearing both against the first interconnector and against the second interconnector; a second seal, arranged at the periphery of the anode of the individual cell and bearing both against the second interconnector and against the electrolyte; the second seal being based on glass and/or glass-ceramic; mechanical means for assembling the interconnectors with one another, suitable for clamping the first seal by compression; at least one electrical contact element arranged between the cathode or the anode and one of the interconnectors; a compression piston comprising a component made of electron-conducting and gastight material, the piston being mounted so as to slide inside the first interconnector, the piston being suitable for compressing the electrical contact element(s); the compressive force of the piston being adjusted as the pressure of steam and hydrogen produced within the module increases; the compression piston being pierced with a conduit for supplying steam, which opens out on the cell on the cathode side so as to carry out homogenous distribution respectively of the steam supplied and the hydrogen produced from the steam supply conduit to a second recovery conduit, and a sealing bellows, assembled by on end thereof to the piston and by another end thereof to the first interconnector; the bellows being suitable both for containing the pressure of the steam and the hydrogen produced inside the module and for deforming along the direction of displacement of the piston. 2. The module according to claim 1 , wherein the second interconnector is pierced with a conduit for supplying draining gas, on the cell on the anode side, so as to carry out homogenous distribution respectively of the draining gas supplied and the oxygen produced from the draining gas supply conduit to the first recovery conduit. 3. The module according to claim 1 , wherein the first seal consists of a washer or ring made of mica. 4. The module according to claim 1 , wherein the at least one electrical contact element comprises a first electrical contact element and a second electrical contact element, the first electrical contact element being arranged between the cathode and one of the interconnectors, and the second electrical contact element being arranged between the anode and the other of the interconnectors. 5. The module according to claim 1 , the second interconnector comprising a second groove formed inside a zone delimited by the second seal, a conduit for supplying draining gas being in communication with the second groove so as to carry out homogenous distribution of the oxygen produced or the draining gas supplied, to the oxygen recovery conduit of the second interconnector. 6. The module according to claim 1 , wherein the individual electrochemical cell (C 1 ), the first and second interconnectors, the first and second seals, the piston and the bellows are of axisymmetrical form about a central axis (X), the steam supply conduit and/or a conduit for supplying draining gas opening out along the central axis (X). 7. The module according to claim 1 , wherein a metal component of the first and/or the second interconnector and/or the piston are made of ferritic steel containing approximately 20% chromium. 8. The module according to claim 1 , wherein the bellows are made of ferritic steel containing approximately 20% chromium. 9. The module according to claim 1 , the first and/or second interconnector comprising a first groove formed between the first seal and the cell (C 1 ), the steam supply conduit being in communication with the first groove so as to carry out homogenous distribution of the steam supplied and produced hydrogen to the second recovery conduit. 10. The module according to claim 1 , wherein: the first and second interconnectors are each pierced with an additional conduit for supplying steam; the two additional supply conduits being connected to one another via an electrically insulating connection tube; the additional supply conduit of the first interconnector being connected to the supply conduit pierced in the piston by a pipe outside the module; the first seal has, within it, a third seal, inside which the connection tube is accommodated. 11. A process for operating an electrolysis or co-electrolysis module (M 1 ) according to claim 1 , according to which: the supply conduits of the piston is supplied with steam or with a mixture of stream and another gas chosen from carbon dioxide and nitrogen dioxide; as the pressure rises within the module, the compressive force applied by the piston to the electrical contact element(s) is adjusted; the hydrogen or the hydrogen and nitrogen or carbon monoxide produced by steam electrolysis or co-electrolysis are recovered. 12. The operating process according to claim 11 , according to which a supply conduit of the second interconnector is supplied with draining gas, the pressure of the draining gas supplied being substantially equal to that of the steam or of the mixture of steam and the other gas, and the oxygen produced is recovered. 13. A module, intended to form an individual unit of a fuel cell of SOFC type, comprising: an individual electrochemical cell (C 1 ) formed of a cathode, or an anode and of an electrolyte inserted between the cathode and the anode, a first and a second device each forming an electrical and fluid tight interconnector, each consisting of a component made of electron-conducting and gastight material; the first and second interconnectors being arranged on either side of the individual cell; the second interconnector being pierced with a conduit for recovering water produced, at a periphery of the cell on an anode side; the second interconnector being pierced with a conduit for supplying air or oxygen, which opens out at a periphery of the cell on a cathode side, and with a conduit for recovering surplus air or oxygen, which opens out at a periphery of the cell on the cathode side so as to carry out homogenous distribution of the air or oxygen from the air or oxygen supply conduit to a second air or oxygen recovery conduit; a first electrically insulating seal arranged at the periphery of the individual cell and bearing both against the first interconnector and against the second interconnector; a second seal, arranged at the periphery of the anode of the individual cell and bearing both against the second interconnector and against the electrolyte; the second seal being based on glass and/or glass-ceramic; mechanical means for assembling the interconnectors with one another, suitable for clamping the first seal by compression; at least one electrical contact element arrang