Abstract
With the increasing awareness of environmental protection and sustainable manufacturing, the environmental impact of laser additive manufacturing (LAM) technology has been attracting more and more attention. Aiming to quantitatively analyze the energy consumption and extract possible ways to save energy during the LAM process, this investigation studies the effects of input variables including laser power, scanning speed, and powder feed rate on the overall energy consumption during the laser deposition processes. Considering microhardness as a standard quality, the energy consumption of unit deposition volume (ECUDV, in J/mm3) is proposed as a measure for the average applied energy of the fabricated metal part. The potential energy-saving benefits of the ultrasonic vibration–assisted laser engineering net shaping (LENS) process are also examined in this paper. The experimental results suggest that the theoretical and actual values of the energy consumption present different trends along with the same input variables. It is possible to reduce the energy consumption and, at the same time, maintain a good part quality and the optimal combination of the parameters referring to Inconel 718 as a material is laser power of 300 W, scanning speed of 8.47 mm/s and powder feed rate of 4 rpm. When the geometry shaping and microhardness are selected as evaluating criterions, American Iron and Steel Institute (AISI) 4140 powder will cause the largest energy consumption per unit volume. The ultrasonic vibration–assisted LENS process cannot only improve the clad quality, but can also decrease the energy consumption to a considerable extent.
Highlights
As a widely used additive manufacturing technology, laser engineering net shaping (LENS) is serving as one of the key technologies in the direct manufacturing or repairing of metal parts.Starting from a computer-aided design (CAD) solid file, the LENS process produces parts layer by layer with the heat input of a high-powered laser
LENS has been successfully applied in the direct fabrication of complex structural components [3], functionally graded coatings [4], high-value-added components repair [5], and special industries such as aerospace, defense, biomedical, etc. [6]
The the results suggest that the ultrasonic vibration–assisted process onlybut improve clad
Summary
As a widely used additive manufacturing technology, laser engineering net shaping (LENS) is serving as one of the key technologies in the direct manufacturing or repairing of metal parts. Starting from a computer-aided design (CAD) solid file, the LENS process produces parts layer by layer with the heat input of a high-powered laser. Being different from other additive manufacturing processes, LENS can fabricate near-net-shaped prototypes, high quality metal parts, and even special tooling for injection molds [2]. LENS has been successfully applied in the direct fabrication of complex structural components [3], functionally graded coatings [4], high-value-added components repair [5], and special industries such as aerospace, defense, biomedical, etc. LENS has been successfully applied in the direct fabrication of complex structural components [3], functionally graded coatings [4], high-value-added components repair [5], and special industries such as aerospace, defense, biomedical, etc. [6].
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