Oxidation kinetics of Ti6Al4V alloy deposited by wire arc additive manufacturing using argon gas as processing atmosphere (10 pages)

J.E. Ordaz Cervantes; R. Morales Estrella; N. Ortiz Lara; E. Reyes Gordillo; D.G. Espinosa Arbeláez

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Oxidation kinetics of Ti6Al4V alloy deposited by wire arc additive manufacturing using argon gas as processing atmosphere (10 pages)

J.E. Ordaz-Cervantes ^[1] ; R. Morales-Estrella ^[1] ; N. Ortiz-Lara ^[1] ; E. Reyes-Gordillo ^[1] ; D.G. Espinosa-Arbeláez ^[2]
1. [1] Universidad Michoacana de San Nicolás de Hidalgo
  
  Universidad Michoacana de San Nicolás de Hidalgo
  
  México
2. [2] Centro de Ingeniería y Desarrollo Industrial (CIDESI), Querétaro, México
Localización: Revista Mexicana de Física, ISSN-e 0035-001X, Vol. 70, Nº. 5, 2024
Idioma: inglés
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Resumen
- Ti6Al4V alloy is currently the most common metal alloy of theα+βphase type, its application is increasing as it has excellent properties at elevated temperatures. The main users of Ti6Al4V alloy are industries such as aerospace, naval, and biomedical; therefore, Ti6Al4V alloy is one of the most studied material worldwide to manufacture low weight and corrosion resistant components. One of the great advantages that Ti6Al4V alloy offers is the possibility of manufacturing components in situ by means of additive technologies. Similar studies, in additive manufacturing, have reported the formation of titanium oxide on the surface of the material, followed by an oxygen-enriched region called “α-case”. By means of thermogravimetric analysis, the oxidation effect on the surface of Ti6Al4V samples, obtained by wire arc additive manufacturing as well as samples from conventional manufacture, were studied. Argon gas, with an oxygen partial pressure of 1×10^(−5) atm, was used as the oxidation atmosphere within a range of 823 to 1223K (550◦C to 950◦C) and oxidation times of 60 min and 180 min. For the oxidation reaction, the kinetic analyses led to calculate the activation energy as 250 kJ/mol and 166 kJ/mol for the Ti6Al4V alloy processed by conventional and additive manufacturing, respectively. The results of the thermogravimetric analyses were fitted to a parabolic-type kinetic model. Furthermore, a mathematical model was proposed to predict the oxidation kinetics. The experimental data were fitted to the mathematical model in the range of 1023-1223K (750-950◦C) for Ti6Al4V alloy by wire arc additive manufacturing. The oxidized micro-structures were analyzed by optical and scanning electron microscopy (SEM) findingα-case on the surface of the samples.