초록 ▼

Highly dense shaped parts are produced with a powder metallurgic process. The parts are formed of an alloy that, besides of at least 20 weight % chromium, consists of iron and one or several additional alloy portions that in sum do not amount to more than 10 weight %. The part is produced by pressin

Highly dense shaped parts are produced with a powder metallurgic process. The parts are formed of an alloy that, besides of at least 20 weight % chromium, consists of iron and one or several additional alloy portions that in sum do not amount to more than 10 weight %. The part is produced by pressing and sintering to near final shape a ready-to-press powder where the additional alloy portions are introduced in form of a master-alloy powder. The master-alloy may contain the following variations: the additional alloy portions and the iron portions; or the additional alloy portions, the iron parts, and the chromium portions; or additional alloy portions and the chromium portions.

대표청구항 ▼

We claim: 1. A powder-metallurgic method, which comprises: providing a ready-to-press powder with grain fractions having a grain size of about 45 μm to about 160 μm and defining an alloy having a portion of at least 20 weight % elementary chromium powder, a master-alloy powder of iron, an

We claim: 1. A powder-metallurgic method, which comprises: providing a ready-to-press powder with grain fractions having a grain size of about 45 μm to about 160 μm and defining an alloy having a portion of at least 20 weight % elementary chromium powder, a master-alloy powder of iron, and at least one additional alloy portion selected from the group consisting of metallic alloy portions and ceramic alloy portions in an aggregate of no more than 10 weight %; wherein the additional alloy portions are added into the ready-to-press powder exclusively in form of a master-alloy powder, and the master-alloy powder is a pre-alloyed powder consisting of: a pre-alloy with the additional alloy portions and the iron portion; and substantially without intermediate mechanical alloying of the ready-to-press powder, pressing the ready-to-press powder in a matrix press to form a pressed powder compact and sintering the pressed powder compact to near final shape of a highly dense part formed of an alloy containing at least 20 weight % chromium, iron, and the at least one additional alloy portion of not more than 10 weight %. 2. The powder-metallurgic method according to claim 1, which comprises pressing the powder mixture with pressing rams having a plurality of parts, wherein the parts are coordinated with a geometry of the shaped part to be produced and provided with a wear protection layer at least at a surface in contact with the powder. 3. The powder-metallurgic method according to claim 1, which comprises pressing the powder to form an interconnector of a fuel cell. 4. The powder-metallurgic method according to claim 1, wherein the ready-to-press powder consists of 95 weight % chromium and 5 weight % of a master-alloy of iron with 0.5 to 0.8 weight % yttrium. 5. The powder-metallurgic method according to claim 1, wherein the ready-to-press powder consists of 20 to 30 weight % chromium and 70 to 80 weight % of a master-alloy of iron with 0.5 to 0.8 weight % rare earth metals. 6. The powder-metallurgic method according to claim 5, which comprises selecting yttrium as the rare earth metal. 7. The powder-metallurgic method according to claim 3, which comprises galvanically applying a chromium layer on surfaces of the pressed and sintered interconnector. 8. The powder-metallurgic method according to claim 3, which comprises carburizing surfaces of the pressed and sintered interconnector by applying a graphitic plate and a following heat treatment at a temperature of between 1100�� C. and 1300�� C. for 12 to 48 hours. 9. The powder-metallurgic method according to claim 1, wherein the pre-alloyed powder of the master alloy powder is a pre-alloy produced substantially without mechanical alloying. 10. The powder-metallurgic method according to claim 1, wherein the pressing step comprises introducing the ready-to-press powder into a matrix press with pressing rams and dies configured to shape an interconnector of a fuel cell. 11. A powder-metallurgic method, which comprises: providing a ready-to-press powder with grain fractions having a grain size of about 45 μm to about 160 μm and defining an alloy having a portion of at least 20 weight % chromium, a portion of iron, and at least one additional alloy portion selected from the group consisting of metallic alloy portions and ceramic alloy portions in an aggregate of no more than 10 weight %; wherein the additional alloy portions are added into the ready-to-press powder exclusively in form of a master-alloy powder, and the master-alloy powder is a pre-alloyed powder selected from the group consisting of: a pre-alloy with the additional alloy portions and the iron portion; a pre-alloy with the additional alloy portions, the iron portion, and the chromium portion; and a pre-alloy with the additional alloy portions and the chromium portion; and substantially without intermediate mechanical alloying of the ready-to-press powder, pressing the powder mixture with pressing rams having a plurality of parts to form a pressed powder compact, wherein the parts of the pressing rams are coordinated with a geometry of the shaped part to be produced and provided with a wear protection layer at least at a surface in contact with the powder, and sintering the pressed powder compact to near final shape of a highly dense part formed of an alloy containing at least 20 weight % chromium, iron, and the at least one additional alloy portion of not more than 10 weight %.