Abstract
Heat input is a crucial factor affecting the quality in blade additive manufacturing repairing. First, a moving heat source model was established, and through numerical analysis and experimental comparison, the optimal geometric parameters of the heat source model for ultrathin blade repair were obtained. Second, a heat transfer model is established based on the optimal heat source model. By analyzing the thermophysical properties of different alloys, the heat input range of the blade was calculated. By heat transfer calculation under different heat inputs, the heat transfer model of blade repair was optimized. Then, a mathematical model of additive height is established. The optimized heat transfer model is used to solve the temperature distribution of the additive section with time under different wire feeding speeds through numerical analysis, which further reduced the heat input range. Third, the experiments are carried out based on the results of numerical analysis. The evolution law of the microstructure and heat input rate of the additive manufacturing zone was revealed, and the optimal heat input parameters were obtained. Under the optimal parameters, the segregation zone disappeared; hence, the test data were close to the base metal, and the additive manufacturing zone achieved better quality. The results and methods are of great guiding significance for the optimization design in additive manufacturing repair of the aero blades. The study also contributes to carrying out a series of research on heat transfer of ultrathin nickel-based alloy welding.
Highlights
Inconel 718 is a nickel-based superalloy which is strengthened by face-centered cube c’ (Ni3X with X Nb, Ti, or Al) and body-centered cube c′′ (Ni3Nb) [1, 2]
Durocher and Richards [13] point out that voltage and current were the most significant process parameters affecting the crack density of microwelded deposits and that using lower values for voltage and current reduces void content and crack density. e study of Saravanan et al [14] investigated the properties of different heat input zones with different macrostructures for low, middle, and higher heat input, respectively
Based on microplasma arc welding (MPAW) additive manufacturing repair, this study aims to obtain a good matching scheme of heat input and related parameters through theoretical modeling, numerical analysis, and experimental verification
Summary
Inconel 718 is a nickel-based superalloy which is strengthened by face-centered cube c’ (Ni3X with X Nb, Ti, or Al) and body-centered cube c′′ (Ni3Nb) [1, 2]. It is widely used in the aviation and aerospace industries because of its good properties. E additive manufacturing of the blade is high standard welding, which is the most important step affecting blade postrepair performance. E heat input is a key factor affecting the microstructure and properties of the weld zone in the welding process of alloy [4,5,6]. Wu et al [15] reviewed the status and existing problems of numerical simulation of composite heat source welding process, Mathematical Problems in Engineering discussed the research direction and development trend of the field of surfacing welding, and provided the theoretical basis for the optimization of welding process and process control
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