Abstract
Monitoring surface quality during machining has considerable practical significance for the performance of high-value products, particularly for their assembly interfaces. Surface roughness is the most important metric of surface quality. Currently, the research on online surface roughness prediction has several limitations. The effect of tool wear variation on surface roughness is seldom considered in machining. In addition, the deterioration trend of surface roughness and tool wear differs under variable cutting parameters. The prediction models trained under one set of cutting parameters fail when cutting parameters change. Accordingly, to timely monitor the surface quality of assembly interfaces of high-value products, this paper proposes a surface roughness prediction method that considers the tool wear variation under variable cutting parameters. In this method, a stacked autoencoder and long short-term memory network (SAE–LSTM) is designed as the fundamental surface roughness prediction model using tool wear conditions and sensor signals as inputs. The transfer learning strategy is applied to the SAE–LSTM such that the surface roughness online prediction under variable cutting parameters can be realized. Machining experiments for the assembly interface (using Ti6Al4V as material) of an aircraft’s vertical tail are conducted, and monitoring data are used to validate the proposed method. Ablation studies are implemented to evaluate the key modules of the proposed model. The experimental results show that the proposed method outperforms other models and is capable of tracking the true surface roughness with time. Specifically, the minimum values of the root mean square error and mean absolute percentage error of the prediction results after transfer learning are 0.027 μm and 1.56%, respectively.
Highlights
Surface quality has a critical impact on the reliability and lifetime of high-value products [1–3], such as rockets, spacecraft, and aircraft
mean absolute percentage error (MAPE) as the metrics to compare the performance of the proposed surface roughness prediction model with the ones in [32,56–58]
The machined surface quality of assembly interfaces is critical to the final quality of an aircraft
Summary
Surface quality has a critical impact on the reliability and lifetime of high-value products [1–3], such as rockets, spacecraft, and aircraft. The surface quality of the assembly interfaces of these products directly affects the final product quality. The assembly interfaces of an aircraft connect adjacent large-scale aircraft components (e.g., wings, tails, and fuselages). The machining process mainly includes milling the assembly interface plane and drilling the connecting holes. Interfaces are characterized by a wide distribution distance, difficult-to-cut materials, and an uneven machining allowance distribution, leading to severe tool wear during the machining process. Surface quality is difficult to control and directly measure [4]. In aircraft assembly, ensuring the surface quality of assembly interfaces is critical to the final quality of the aircraft. There are many parameters affecting surface quality, such as surface roughness (2-D and 3-D surface roughness), surface waviness, surface form, etc. There are many parameters affecting surface quality, such as surface roughness (2-D and 3-D surface roughness), surface waviness, surface form, etc. [5,6], among which, surface roughness parameters
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