Gas inlet for SOEC unit

The invention claimed is: 1. Solid oxide electrolysis cell stack comprising: a plurality of stacked cell units, each unit comprises a cell layer located between a pair of spaced interconnect layers, wherein said interconnect layers respectively separate one cell unit from an adjacent cell unit in the cell stack, wherein one of said interconnect layers in the at least one cell unit has at least one primary gas inlet opening in flow communication with at least one secondary gas inlet opening in said cell layer, wherein said primary gas inlet opening has a greater cross-sectional flow area than said secondary gas inlet opening which partly overlaps said primary gas inlet opening such that a portion of the flow from the primary gas inlet is blocked and common cross-sectional flow areas of the primary and secondary gas inlet openings define a common gas inlet zone where inlet gas flows from the primary gas inlet opening to the secondary gas inlet opening. 2. Solid oxide electrolysis cell stack according to claim 1 , wherein the interconnect layer comprising the at least one primary gas inlet opening and the cell layer comprising the at least one secondary gas inlet opening abut one another. 3. Solid oxide electrolysis cell stack according to claim 1 , wherein the cell layer comprising the at least one secondary gas inlet opening further comprise at least one protrusion forming at least one gas inlet flow guide. 4. Solid oxide electrolysis cell stack according to claim 3 , wherein said at least one gas inlet flow guide at least partly overlaps a part of said at least one primary gas inlet opening and thereby forms at least one multiple channel gas inlet. 5. Solid oxide electrolysis cell stack according to claim 1 , wherein another of said interconnect layers in at least one cell unit has at least one primary gas outlet opening and wherein the cell layer of the same cell unit has at least one secondary gas outlet opening, wherein said primary gas outlet opening and said secondary gas outlet opening partly overlap to define a common cross-sectional flow area lesser in dimension than a cross-sectional flow area of said primary gas outlet opening, the overlap defines a common gas outlet zone where outlet gas flows from the primary gas outlet opening to the secondary gas outlet opening. 6. Solid oxide electrolysis cell stack according to claim 5 , wherein the cell layer comprising the at least one secondary gas outlet opening further comprises at least one protrusion forming at least one gas outlet flow guide. 7. Solid oxide electrolysis cell stack according to claim 6 , wherein said at least one gas outlet flow guide at least partly overlaps a part of said at least one primary gas outlet opening and thereby forms at least one multiple channel gas outlet. 8. Solid oxide electrolysis cell stack according to claim 1 , wherein said unit further comprises at least one spacer layer. 9. Solid oxide electrolysis cell stack according to claim 1 , wherein the at least one primary gas inlet opening is a cut through hole, a cut through opening, an indentation or a combination of these. 10. Solid oxide electrolysis cell stack according to claim 1 , wherein the at least one secondary gas inlet opening is a cut through hole, a cut through opening, an indentation or a combination of these. 11. Solid oxide electrolysis cell stack according to claim 5 , wherein the at least one primary gas inlet opening or the at least one primary gas outlet opening is a cut through hole, a cut through opening, an indentation or a combination of these. 12. Solid oxide electrolysis cell stack according to claim 5 , wherein the at least one secondary gas inlet opening or the at least one secondary gas outlet opening is a cut through hole, a cut through opening, an indentation or a combination of these.