D 2005

CARBON AND NITROGEN REDISTRIBUTION IN WELD JOINTS OF HEAT RESISTANT STEELS

SOPOUŠEK, Jiří a Rudolf FORET

Základní údaje

Originální název

CARBON AND NITROGEN REDISTRIBUTION IN WELD JOINTS OF HEAT RESISTANT STEELS

Název česky

Přerozdělení uhlíku a dusíku ve svarových spojích žárovzdorných ocelí

Název anglicky

CARBON AND NITROGEN REDISTRIBUTION IN WELD JOINTS OF HEAT RESISTANT STEELS

Autoři

SOPOUŠEK, Jiří (203 Česká republika, garant) a Rudolf FORET (203 Česká republika)

Vydání

Roma, 1-st International Conference Super-High Strenght Steels, od s. 60/1-9, 9 s. 2005

Nakladatel

Associazione Italiana di Metallurgia

Další údaje

Jazyk

čeština

Typ výsledku

Stať ve sborníku

Obor

10403 Physical chemistry

Stát vydavatele

Itálie

Utajení

není předmětem státního či obchodního tajemství

Kód RIV

RIV/00216224:14310/05:00012734

Organizační jednotka

Přírodovědecká fakulta

ISBN

88-85298-56-7

Klíčová slova anglicky

weldment;phase;DICTRA;CALPHAD;P91;carbonitride
Změněno: 27. 1. 2006 16:07, prof. RNDr. Jiří Sopoušek, CSc.

Anotace

V originále

The present contribution deals with the theoretical modelling of the kinetics of the development of chemical composition and phase profiles of heterogeneous laboratory weld joints of heat resistant steels from the point of view of their long-term stability. The T25 ( 6 CrMoV 8-3-2) heat-resistant ferritic steel currently being developed and the advanced P91 (X10CrMoVNb 10-1) chromium steel, both steels after ion nitriding, homogenisation at 1050şC and weld joining were the subject of study. The basic compositions of materials were approximated as the Fe-Cr-Ni-Mo-V-C-N system. The long-term annealing of the T25+0.1129wt%N | P91+(0.8-0.064wt)N weld joints were simulated at 600şC and 900şC. The simulated results were compared with experimental carbon profile observations. The phase diagrams of the investigated materials were calculated using the CALPHAD approach [1] and applying the STEEL thermodynamic database [2]. The activities of carbon, nitrogen, and other elements were calculated by the same method. The CALPHAD approach complemented with an appropriate diffusion model [3] given in the DICTRA code enabled simulating the phase and element profile evolutions inside the diffusion-affected zone of weld joint. The DIF kinetic database [4] was used to describe the diffusion. In the simulation the coexistence of different phases (carbides, carbonitrides,) was assumed.

Anglicky

The present contribution deals with the theoretical modelling of the kinetics of the development of chemical composition and phase profiles of heterogeneous laboratory weld joints of heat resistant steels from the point of view of their long-term stability. The T25 ( 6 CrMoV 8-3-2) heat-resistant ferritic steel currently being developed and the advanced P91 (X10CrMoVNb 10-1) chromium steel, both steels after ion nitriding, homogenisation at 1050şC and weld joining were the subject of study. The basic compositions of materials were approximated as the Fe-Cr-Ni-Mo-V-C-N system. The long-term annealing of the T25+0.1129wt%N | P91+(0.8-0.064wt)N weld joints were simulated at 600şC and 900şC. The simulated results were compared with experimental carbon profile observations. The phase diagrams of the investigated materials were calculated using the CALPHAD approach [1] and applying the STEEL thermodynamic database [2]. The activities of carbon, nitrogen, and other elements were calculated by the same method. The CALPHAD approach complemented with an appropriate diffusion model [3] given in the DICTRA code enabled simulating the phase and element profile evolutions inside the diffusion-affected zone of weld joint. The DIF kinetic database [4] was used to describe the diffusion. In the simulation the coexistence of different phases (carbides, carbonitrides,) was assumed.

Návaznosti

GA106/03/0636, projekt VaV
Název: Teoretické modelování a experimentální studium strukturní stability moderních žárupevných ocelí a jejich svarů
MSM0021622410, záměr
Název: Fyzikální a chemické vlastnosti pokročilých materiálů a struktur
Investor: Ministerstvo školství, mládeže a tělovýchovy ČR, Fyzikální a chemické vlastnosti pokročilých materiálů a struktur