Effect of heat input in Fe-based nanostructured weld overlay

A. GUALCO; HERNÁN G. SVOBODA; E. S. SURIAN

Welding International

Taylor abd Francis

Lugar: Abngdon; Año: 2015 vol. 29 p. 847 - 855

In the last few years, several welding consumables have been developed that deposit hard iron-based nanostructured alloycoverings with high resistance to abrasive wear. The erosive and abrasive wear resistances are mainly controlled by thechemical composition and the microstructure. In turn, the microstructure of the deposited metal can show variations with theused welding procedure, particularly in relation to the heat input. The operating parameters that define the heat input(voltage, current and welding speed) affect aspects such as bead geometry (wide, penetration and reinforcement) anddilution with the base material. The purpose of this article is to study the effect of heat input on the geometric characteristicsof the bead, the dilution and the microstructural evolution of a nanostructured iron-based alloy deposited by FCAW. Severalsamples with heat input between 0.5 and 3.5 kJ/mm were welded. A dimensional study was carried out for each weldedcoupon, the chemical composition was analysed and the microstructure was characterized using optical and electronicscanning microscopy and X-ray diffraction. Microhardness, crystallite size and degree of dilution were also measured. Greatinfluence in these conditions in the process was observed about the geometry of the bead. The dilution varied between 30%and 40%; microhardness of the deposit was found between 800 and 870 HV1, and the size of the crystallite varies between105 and 130 nm, depending on process variables used. The highest hardnesses and the lowest crystallite sizes were obtainedwith the lowest heat input, associated with a lower dilution.