Título
Characterization of friction coefficient at near solidus forming (NSF) conditions using T-shape compression testAutor-a (de otra institución)
Otras instituciones
Universidad de DeustoVersión
Version publicada
Derechos
© 2024 The AuthorsAcceso
Acceso abiertoVersión del editor
https://doi.org/10.1016/j.jmapro.2024.07.009Publicado en
Journal of Manufacturing Processes Vol. 124. Pp. 1259-1272. August, 2024Primera página
1259Última página
1272Editor
ElsevierPalabras clave
Near solidus forming (NSF)Finite element model
Geometric parameter indexes
Inverse modelling
Materia (Tesauro UNESCO)
Tecnología de materialesClasificación UNESCO
FricciónMecánica
Resumen
Amidst the escalating demand for sustainable manufacturing practices aimed at mitigating global emissions and waste, industries are actively seeking novel forming solutions to address these pressing g ... [+]
Amidst the escalating demand for sustainable manufacturing practices aimed at mitigating global emissions and waste, industries are actively seeking novel forming solutions to address these pressing global challenges. Near Solidus Forming (NSF) processes emerge as a promising alternative to confront such issues, offering the capability to fabricate intricate components reliably while minimizing material waste and energy consumption. This promising manufacturing process is still in its developmental stages for industrial applications, necessitating further exploration and understanding of various factors such as friction, heat transfer, and others. From the literature review, a lack of friction data at these temperatures has been identified. Therefore, this study is dedicated to the advanced characterization of the friction coefficient for Near Solidus Forging (NSF) operations. With that aim, T-shape experimental tests of 42CrMo4 alloy steel have been conducted at high temperatures (up to 1360 °C). Additionally, a lack of consensus on the correct T-shape testing and inverse analysis procedure has been noted. Consequently, apart from the experimental work, an in-depth analysis of the friction coefficient identification procedure has been conducted. As a result, a new geometrical output index is proposed, highly sensitive to the friction coefficient and therefore more reliable compared to state-of-the-art indexes. Furthermore, the influence of the selected geometrical output index and the consideration of sample-to-sample transfer and holding times were studied. Results showed that the increase in workload to consider the sample-to-sample transfer and holding times is not worthwhile, as assuming the average values lead to significantly less work with little impact in the final results (<5 % of error). The study also concludes that a friction coefficient of 0.25, 0.45 and 0.6 has been identified at temperatures of 1250 °C, 1300 °C and 1360 °C, respectively. Additionally, the result of thermal camera showed good agreement with the thermocouple data. Overall, in this study a robust and reliable T-shape testing, and friction coefficient identification procedure is proposed and validated. [-]
Financiador
Comisión EuropeaGobierno Vasco
Gobierno de España
Programa
Research Fund for Coal and Steel (RFCS)Elkartek 2020
Ayudas a Proyectos de Generación de Conocimiento y a actuaciones para la formación de personal investigador predoctoral
Número
800763KK-2020-00087
PID2022-139130OA-I00
URI de la ayuda
Sin informaciónSin información
Sin información
Proyecto
Hybrid Semi-Solid Forming (HSSF)Procesos de fabricación excelentes para propiedades máximas frente a la corrosión de aceros de altas prestaciones (PROMAX)
Exploración del uso de aleaciones de Alta Entropía como material sustitutibo para una movilidad sotenible y descarbonizada (HEAPLAS)
Colecciones
- Artículos - Ingeniería [684]
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