Process for producing an interconnector of a high-temperature fuel cell

The invention claimed is: 1. A process of producing an interconnector for a high-temperature fuel cell, the process comprising: providing a powder press with dies substantially corresponding to a final shape of the interconnector, with a basic body having a multiplicity of elevations projecting from the basic body with inclined side surfaces; providing a chromium-based powder containing elemental chromium and filling the powder into a female die of the powder press; pressing the chromium-based powder to form the basic body having a shape of a disk or a plate with the elevations defining flow channels of the high-temperature fuel cell and the elevations rising from the basic body with inclined side surfaces having an angle of inclination of between 115° and 160°; subsequently ejecting the basic body from the dies of the powder press and sintering to form the interconnector; and performing the pressing with parameters of the powder press such that, after sintering, the interconnector has a substantially uniform density throughout the basic body and the elevations, and the density is sufficient to render the interconnector suitable for use in a solid oxide fuel cell. 2. The process according to claim 1 , which comprises forming the elevations as web-shaped or knob-shaped elevations projecting from the basic body with inclined side surfaces. 3. The process according to claim 1 , wherein the pressing step is a multi-stage pressing step including a first pressing stage and a second pressing stage each performed with mutually different dies, and wherein: the first pressing stage comprises pressing boundary surfaces of the basic body to near final shape as far as transition regions of the elevations and simultaneously pressing the elevations to an oversize, defined with a projection height h′ from the basic body being greater than a projection height h from the basic body in a finally pressed state by 10%-150%, and with side surfaces of the elevations enclosing an angle of inclination α′ in a range from 90°-150° with a respectively adjacent boundary surface of the basic body; and the second pressing stage comprises pressing the elevations to near final shape and thereby increasing the angle of inclination α′ to the angle of inclination of between 115° and 160°. 4. The process according to claim 3 , which comprises forming the projection height h′ by 30%-100% greater than the final projection height h in the finally pressed state. 5. The process according to claim 3 , which comprises forming the angle of inclination α′ within a range from 110° to 130°, and forming the angle of inclination α within a range from 115° to 160°. 6. The process according to claim 3 , which comprises mixing the powder with an amount of pressing aid wax and pre-sintering subsequently to the first pressing stage. 7. The process according to claim 1 , wherein the chromium-based powder contains the elemental chromium, an iron component, and one or more additional metallic and/or ceramic alloy components of a total of at most 40% by weight, and which comprises introducing the additional alloy components into the powdery raw materials as a pre-alloy with iron. 8. A process for producing a molding with a basic body having a multiplicity of elevations merging into the basic body with inclined side surfaces, the method which comprises the following steps: providing a chromium-based powder containing elemental chromium and pressing the chromium-based powder in a two-stage pressing operation with a first pressing stage and a subsequent, second pressing stage; and in the first pressing stage, providing the powder press with a first set of dies and pressing the chromium-based powder, wherein the dies are set to press the elevations with a defined oversize resulting from the first pressing stage with: a projection height h′ from the basic body greater than a projection height h from the basic body in a finally pressed state by 10%-150%; and side surfaces of the elevations enclosing an angle of inclination α′ between 90° and 150° with a respectively adjacent boundary surface of the basic body; in the second pressing stage, providing the powder press with a second set of dies, different from the first set of dies, and pressing the elevations with the second dies to near final shape, by reducing the height of the elevations from the height h′ to the height h by a greater amount than a reduction in a thickness of the basic body in the adjacent boundary surfaces and by increasing the angle of inclination α′ to α value a in a range from 95°-170°; and subsequently sintering the basic body to produce the molding. 9. The process according to claim 8 , which comprises mixing the powder with a minor amount of micro wax and pre-sintering subsequently to the first pressing stage. 10. A process of producing an interconnector for a high-temperature fuel cell, the process comprising: providing a powder press with dies substantially corresponding to a final shape of the interconnector, with a basic body having a multiplicity of elevations projecting from the basic body with inclined side surfaces; providing a chromium-based powder containing a major proportion of elemental chromium and a minor proportion of at least one additional alloying metal, and filling the powder into a female die of the powder press; pressing the chromium-based powder to form the basic body having a shape of a disk or a plate with the elevations defining flow channels of the high-temperature fuel cell and the elevations rising from the basic body with inclined side surfaces having an angle of inclination of between 115° and 160°; subsequently ejecting the basic body from the dies of the powder press and sintering to form the interconnector for the high-temperature fuel cell.