Build cylinder arrangements for machines for layered production of three-dimensional objects having a fiber metal seal

What is claimed is: 1. A build cylinder arrangement for a machine for the layered production of three-dimensional objects by sintering or melting with a high-energy beam a powdered material, the build cylinder arrangement comprising: a base member; a piston configured to be moveable on an inner side of the base member along a central axis of the base member, wherein the piston comprises a substrate at an upper side thereof; and a seal for sealing the powdered material in abutment with the inner side of the base member, wherein the seal for sealing the powdered material comprises a circumferential fiber metal seal comprising metal fibers that are pressed together, wherein the pressed metal fibers are arranged with resilient compression stress between the piston and the inner side of the base member, wherein the substrate and the seal for sealing the powdered material are constructed on an upper portion of the piston, which is releasably arranged on a remaining portion of the piston, and wherein the remaining portion of the piston includes a heating device arranged to heat the substrate to an operating temperature defined as 500° C.≤operating temperature ≤1000° C. 2. The build cylinder arrangement of claim 1 , wherein the metal fibers that are pressed together form a knitted metal fabric. 3. The build cylinder arrangement of claim 2 , wherein the knitted metal fabric comprises a circumferentially closed knitted stocking. 4. The build cylinder arrangement of claim 1 , wherein the fiber metal seal is resiliently compressed with respect to its diameter by at least 0.4 mm or by at least 0.8%, or both by at least 0.4 mm and by at least 0.8%, as a result of the introduction into the base member at ambient temperature. 5. The build cylinder arrangement of claim 1 , wherein a material or density, or both a material and a density, of the fiber metal seal is selected such that a thermal expansion of the inner diameter of the base member and a thermal expansion of the outer diameter of the fiber metal seal between ambient temperature and the operating temperature differ by a maximum factor of 2. 6. The build cylinder arrangement of claim 5 , wherein the thermal expansion of the inner diameter of the base member and the thermal expansion of the outer diameter of the fiber metal seal between ambient temperature and the operating temperature differ by a maximum factor of 1.5. 7. The build cylinder arrangement of claim 1 , wherein the fiber metal seal is inserted into a groove at an outer side of the piston, and the fiber metal seal radially overhangs the groove. 8. The build cylinder arrangement of claim 7 , wherein the groove is constructed by a first seal carrier portion and a second seal carrier portion that is rotatable with a bayonet-type mechanism with respect to the first seal carrier portion. 9. The build cylinder arrangement of claim 1 , wherein the fiber metal seal comprises a material that is resistant to corrosion in atmospheric oxygen at the operating temperature. 10. The build cylinder arrangement of claim 1 , wherein the fiber metal seal comprises a material having a yield strength R p,0.2 ET at the operating temperature that is at least 75% of yield strength R p,0.2 ET at ambient temperature after the fiber metal seal has been kept for 100 hours at the operating temperature. 11. The build cylinder arrangement of claim 1 , wherein the fiber metal seal comprises a high-grade steel. 12. The build cylinder arrangement of claim 11 , wherein the fiber metal seal comprises Ni-containing high-grade steel, or a Ni alloy. 13. The build cylinder arrangement of claim 1 , wherein the upper portion of the piston is releasably arranged on the remaining portion of the piston with a clamping mechanism or a torsion prevention means, or both a clamping mechanism and a torsion prevention means. 14. The build cylinder arrangement of claim 1 , wherein the remaining portion of the piston includes a central portion having the heating device arranged to heat the substrate to the operating temperature. 15. The build cylinder arrangement of claim 14 , wherein the remaining portion further comprises a lower portion of the piston having a cooling device arranged to cool the piston, wherein a thermal insulation is provided between the central portion and the lower portion, and the lower portion of the piston has a circumferential seal in abutment with the inner side of the base member for sealing gas, wherein the circumferential seal is comprised at least partially of an elastomer material. 16. The build cylinder arrangement of claim 15 , wherein the seal for sealing gas comprises a hydraulic or pneumatic seal whose outer diameter can be adjusted by a pressure of hydraulic fluid or gas in the seal. 17. The build cylinder arrangement of claim 1 , wherein the base member comprises an insulation member that is substantially cylindrical and forms at least the inner side of the base member, wherein the insulation member is made of a material with a specific thermal conductivity ≤3 W/(m*K). 18. The build cylinder arrangement of claim 17 , wherein the material of the insulation member is ceramic or glass. 19. The build cylinder arrangement of claim 18 , wherein the glass is quartz glass. 20. The build cylinder arrangement of claim 19 , wherein the quartz glass is opaque.