Evaluation of Austenitic Stainless Steel ER308 Coating on H13 Tool Steel by Robotic GMAW Process
Author:
Hernandez-Flores Jorge Eduardo12ORCID, Rodriguez-Vargas Bryan Ramiro3ORCID, Stornelli Giulia3ORCID, Pérez Argelia Fabiola Miranda4, García-Vázquez Felipe de Jesús1, Gómez-Casas Josué1, Di Schino Andrea3ORCID
Affiliation:
1. Faculty of Engineering, Universidad Autonoma de Coahuila, Ciudad Universitaria, Arteaga 25350, Mexico 2. Corporacion Mexicana de Investigación en Materiales S.A., Ciencia y Tecnología 790, Saltillo 400, Saltillo 25290, Mexico 3. Dipartimento di Ingegneria, Università degli Studi di Perugia, Via G. Duranti 93, 06125 Perugia, Italy 4. Engineering Department, Mechatronics, Bionics and Aerospace, Universidad Popular Autonoma del Estado de Puebla, 17 Sur, 901, Barrio de Santiago, Puebla 72410, Mexico
Abstract
Within the drilling, petrochemical, construction, and related industries, coatings are used to recover components that failed during service or to prevent potential failures. Due to high stresses, such as wear and corrosion, which the materials are subjected to, industries require the application of coating between dissimilar materials, such as carbon steels and stainless steels, through arc welding processes. In this work, an austenitic stainless steel (ER308) coating was applied to an H13 tool steel substrate using the gas metal arc welding (GMAW) robotic process. The heat input during the process was calculated to establish a relationship between the geometry obtained in the coating and its dilution percentage. Furthermore, the evolution of the microstructure of the coating, interface, and substrate was evaluated using XRD and SEM techniques. Notably, the presence of martensite at the interface was observed. The mechanical behavior of the welded assembly was analyzed through Vickers microhardness, and a pin-on-disk wear test was employed to assess its wear resistance. It was found that the dilution percentage is around 18% at high heat input (0.813 kJ/mm) but decreases to about 14% with reduced heat input. Microhardness tests revealed that at the interface, the maximum value is reached at about 625 HV due to the presence of quenched martensite. Moreover, increasing the heat input favors wear resistance.
Funder
National Council of Humanities, Sciences and Technologies (CONAHCYT), Mexico
Subject
General Materials Science,Metals and Alloys
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