Effect of autogenous GTAW on the reciprocating sliding wear behavior of a carbon martensitic steel

Cintia Cristiane  Petry Mazzaferro,Daniela Fátima Giarollo,Thalita Cristina de Paula,Breno Basso,Gelsa Edith Navarro Hidalgo

doi:10.4025/actascitechnol.v43i1.50488

Cintia Cristiane Petry Mazzaferro, Daniela Fátima Giarollo

Open Access

https://doi.org/10.4025/actascitechnol.v43i1.50488

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Abstract

Martensitic steels have been successfully employed in resource-based industries where components must endure aggressive conditions. In industrial practice, many parts of these components are joined by welding techniques. The aim of this work was to understand the influence of welding on the wear resistance of quenched and tempered carbon martensitic steel subjected to dry linear reciprocating sliding micro-wear tests. Weld-joints were produced using autogenous Gas Tungsten Arc Welding process (GTAW). Micro-wear tests were performed at base metal (BM), weld metal (WM), coarse grained heat affected zone (CG-HAZ) and lowest hardness region of heat affected zone (LHR-HAZ). LHR-HAZ was softened during welding process so plastic deformation was facilitated, and consequently adhesion, material displacement and micro-ploughing. WM and CG-HAZ presented a similar martensitic structure, which explain the similarities found on wear behavior. These regions presented the lowest worn volume average values (w). It was interesting to note that despite its highest microhardness value, the highest w was observed for BM. For some BM samples, debris had a key role promoting material loss by micro-cutting which causes great extent of material removal compared to other micro-wear mechanisms as micro-ploughing and adhesion. Due to debris action BM also presented a great dispersion in w results. The results suggest that material loss of welded joint and BM was strongly controlled by micro-wear mechanisms.

Highlights

The usage of martensitic steels in resourced-based industries can be effective for minimizing costs due to wear, extending the service life (Mindivan, 2013)
The highest microhardness average value was obtained on base metal (BM) (499 ± 6 HV) followed by weld metal (WM) (452 ± 10 HV) and coarse grained heat affected zone (CG-HAZ) (419 ± 9 HV)
At lowest hardness region of heat affected zone (LHR-HAZ) microhardness value was 253 ± 6 HV, where hardness reduction reached a range of 50% compared to BM

Summary

Introduction

The usage of martensitic steels in resourced-based industries can be effective for minimizing costs due to wear, extending the service life (Mindivan, 2013). The fine grains of their martensitic structure create characteristics features of high strength, toughness, and resistance to abrasive wear (Białobrzeska, Dziurka, Żak, & Bała, 2018; Białobrzeska & Kostencki, 2015; Frydman, Konat, & Pękalski 2008; Mendez et al, 2014). These properties are obtained through a specific combination of thermomechanical processes and a strictly selected chemical composition that includes low quantities of phosphorus and sulphur (Białobrzeska & Kostencki, 2015). The authors highlighted that in their study, micro-cutting was the predominant micro-wear mechanism in material removal

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