Method for producing a sintered component and a sintered component

The invention claimed is: 1. A method for producing a stainless steel component comprising the steps of: providing a stainless steel powder consisting of the following composition by weight: Cr 15-30 wt % Ni 5-25 wt % Si 0.5-3.5 wt % Mn 0-2 wt % S 0-0.6 wt % C 0.001-0.8 wt % N ≤0.3 wt % O ≤0.5 wt % optionally up to 3 wt % of each of the elements Mo, Cu, Nb, V, and Ti, and inevitable impurities up to 1 wt %, Fe balance, agglomerating the stainless steel powder or transferring the stainless steel powder, optionally mixed with lubricants, hard-phase materials, machinability enhancing agents, and graphite, into a paste or feedstock, consolidating the obtained paste, feedstock, or powder into a green component, heating the obtained green component in vacuum or in an atmosphere of hydrogen gas to a temperature of at least 1100° C., sintering the green component at a temperature between 1150-1350° C. in an atmosphere of at least 20% nitrogen gas, wherein the composition of the atmosphere is shifted, such that the component of the atmosphere during the heating is different from the composition of the atmosphere during the sintering, cooling the sintered component at a cooling rate of at most 30° C/min from the sintering temperature to a temperature of ≥1100° C. in an atmosphere of at least 20% nitrogen gas to form M 2 (C,N) carbo-nitrides, cooling the sintered component from 1100° C. to ambient temperature at a cooling rate of at least 30° C/min and high enough to avoid formation of M(C,N) carbo-nitrides yielding a component having at least 12% by weight of Cr in the matrix, wherein the composition of the stainless steel powder in the green component consists of the following composition by weight: Cr 15-30% Ni  5-25% Si 0.5-3.5% Mn 0-2% S   0-0.6% C 0.001-0.8%  N ≤0.3% O ≤0.5% optionally up to 3% of each of the elements Mo, Cu, Nb, V, and Ti, and inevitable impurities up to 1%, Fe balance. 2. The method according to claim 1 , wherein the provided stainless steel powder and the stainless steel powder in the green compact both consist of the following composition by weight: Cr 17-25% Ni  5-20% Si 0.5-2.5% Mn   0-1.5% S   0-0.6% C 0.001-0.8%  N ≤0.3% O ≤0.5% optionally up to 3% of each of the elements Mo, Cu, Nb, V, and Ti, and inevitable impurities up to 1%, Fe balance. 3. The method according to claim 1 , wherein the provided stainless steel powder and the stainless steel powder in the green compact both consist of the following composition by weight: Cr 19-21% Ni 12-14% Si 1.5-2.5% Mn 0.7-1.1% S 0.2-0.4% C 0.4-0.6% N ≤0.3% O ≤0.5% optionally up to 3% of each of the elements Mo, Cu, Nb, V, and Ti, and inevitable impurities up to 1%, Fe balance. 4. The method according to claim 1 , wherein the atmosphere during sintering is one of pure nitrogen, mixtures of nitrogen and hydrogen, mixtures of nitrogen and inert gas, or mixtures of nitrogen and hydrogen and inert gas. 5. The method according to claim 1 , wherein the atmosphere during the sintering comprises up to 10% hydrogen gas. 6. The method according to claim 1 , comprising agglomerating the stainless steel powder.