Abstract
Gas metal arc welding-based wire arc additive manufacturing (GMAW-WAAM) is the most widespread and commonly used technique in the metal additive manufacturing industry. The quality of fabricated parts using GMAW-WAAM largely depends on different process parameters and temperature/heat generation during the process. The dissemination of temperature in the process is considerably affected by path planning. Eventually, the overall precision and the surface quality of the fabricated components get affected. In this chapter, the consequences of temperature dissemination on the process have been analyzed using a finite element analysis-based model. The model simulates the GMAW-WAAM process of 316L stainless steel for a single layer deposition in a specified shape and the temperature dissemination has been documented. The outcome is that at all the turning points, a local temperature accumulation occurs which might degrade the geometric properties of the fabricated component. The developed model can additionally aid in the growth of a responsive supervision and restriction system to control the thermal anomaly.
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https://catalog.ansys.com/product/5b3bc6857a2f9a5c90d32e7e/moving-heat-source?creator=ANSYS%20Inc. Accessed on 10 May 2021
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Srivastava, M., Rathee, S., Dongre, M., Tiwari, A. (2022). Analysis of Temperature Concentration During Single Layer Metal Deposition Using GMAW-WAAM: A Case Study. In: Praveen Kumar, A., Sadasivuni, K.K., AlMangour, B., Abdul bin Majid, M.S. (eds) High-Performance Composite Structures. Composites Science and Technology . Springer, Singapore. https://doi.org/10.1007/978-981-16-7377-1_8
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