Abstract
The present paper aimed at assessing the effect of two thermal management approaches on geometry and productivity of thin-walled structures built by Wire + Arc Additive Manufacturing (WAAM). Thin-walls of ER 5356 (Al5Mg) with different lengths and the same number of layers were deposited via the gas metal arc (GMA) process with the aid of an active cooling technique (near-immersion active cooling—NIAC) under a fixed set of deposition parameters. Then, the same experiment was performed with natural cooling (NC) in air. To characterize the thermal management approaches, the interpass temperature (i.e., the temperature at which subsequent layers are deposited) were monitored by a trailing/leading infrared pyrometer during the deposition time. Finally, thin walls with a fixed length were deposited using the NC and NIAC approaches with equivalent interpass temperatures. As expected, the shorter the wall length the more intense the deposition concentration, heat accumulation, and, thus, geometric deviation. This behavior was more evident and premature for the NC strategy due to its lower heat sinking effectiveness. The main finding was that, regardless of the thermal management technique applied, if the same interpass temperature is selected and maintained, the geometry of the part being built tends to be stable and very similar. However, the total deposition time is somewhat shorter with the NIAC technique due its greater heat sinking advantage. Thus, the NIAC technique facilitates the non-stop manufacturing of small parts and details via WAAM.
Highlights
Introduction iationsThe ASTM F3187 [1] standard guide for directed energy deposition (DED) of metals states that preheating temperature and interpass temperature may be key variables for certain processes and materials
For the natural cooling (NC) condition, the surface of the walls got rougher and assumed a matte aspect, which may be related to the heat accumulation and/or to an insufficient shielding gas protection [20]
The walls deposited under the near-immersion active cooling (NIAC) technique were taller and slender than those ones produced under the NC approach
Summary
The ASTM F3187 [1] standard guide for directed energy deposition (DED) of metals states that preheating temperature and interpass temperature may be key variables for certain processes and materials. This is true for the fabrication of thin-walled structures by Wire + Arc Additive Manufacturing (WAAM) due to its high deposition rate/heat input and a poor heat sinking effect through thin-walled structures. Minimum interpass temperatures are maintained to control the microstructure produced, and, in most cases, they are similar to the preheating temperature. In addition to the microstructure, the interpass temperature has a significant effect on the part
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