Busca avançada
Ano de início
Entree


Synergism between B and Nb Improves Fire Resistance in Microalloyed Steels

Texto completo
Autor(es):
Ferreira, Pedro Pires ; Carvalho, Felipe Moreno ; Ariza-Echeverri, Edwan Anderson ; Delfino, Pedro Meirelles ; Bauri, Luiz Felipe ; Ferreira, Andrei Marx ; Braga, Ana Paola ; Eleno, Luiz Tadeu Fernandes ; Goldenstein, Helio ; Tschiptschin, Andre Paulo
Número total de Autores: 10
Tipo de documento: Artigo Científico
Fonte: METALS; v. 13, n. 1, p. 8-pg., 2023-01-01.
Resumo

The long exposure of structural components to high temperatures (above 600 degrees C) negatively changes their mechanical properties, severely compromising the structural capacity of buildings and other structures in which safety is a primary concern. Developing new cheaper fire-resistant steels with better mechanical and thermal performances represents a challenging, cutting-edge materials science and engineering research topic. Alloying elements such as Nb and Mo are generally used to improve the strength at both room and high temperatures due to the formation of precipitates and harder microconstituents. This study shows that adding small amounts of boron in Nb-microalloyed fire-resistant steels may be crucial in maintaining mechanical properties at high temperatures. The widely used 66% yield-strength criteria for fire resistance was achieved at approximate to 574 degrees C for the B-added alloys. In contrast, for those without boron, this value reached approximate to 460 degrees C, representing a remarkable boron-induced mechanical strengthening enhancement. First-principles quantum mechanics calculations demonstrate that boron additions can lower 11.7% of the vacancy formation energy compared to pure ferrite. Furthermore, for Nb-added steels, the reduction in the vacancy formation energy may reach 33.2%, suggesting that the boron-niobium combination could act as an effective pinning-based steel-strengthening agent due to the formation of B-induced higher-density vacancy-related crystalline defects, as well as other well-known steel strengthening mechanisms reported in the literature. Adding boron and niobium may, therefore, be essential in designing better structural alloys. (AU)

Processo FAPESP: 19/05005-7 - Laboratório de Computação em Materiais para o estudo ab initio da estabilidade de compostos intermetálicos
Beneficiário:Luiz Tadeu Fernandes Eleno
Modalidade de apoio: Auxílio à Pesquisa - Regular
Processo FAPESP: 20/08258-0 - Estudo ab initio de sistemas supercondutores e topológicos
Beneficiário:Pedro Nunes Ferreira
Modalidade de apoio: Bolsas no Brasil - Doutorado