Artificial neural network and multiple regression analysis for predicting abrasive water jet cutting of al 7068 aerospace alloy

Abstract

This study aims to predict machinability and high performance optimum surface roughness ( R a ) by developing multiple regression models and artificial neural network (ANN) model for abrasive waterjet cutting (AWJC) of Aluminum 7068 alloy. Important basic processing parameters such as pump pressure (3500-4000 Bar), nozzle distance (2-5 mm), abrasive flow rate (200-350 g/min), abrasive grain size (100-110, mesh), and nozzle traverse speed (240-300 mm/min) were selected in the study. To examine the effects of these parameters on R a , 32 experiments were conducted using the L32 orthogonal array, and data was collected. Additionally, the most important factors and interactions affecting R a were determined using multiple regression analysis and analysis of variance (ANOVA). The ANN model was designed to have multiple hidden layers using MATLAB. The model was trained and evaluated using experimental data, and its performance was measured using mean squared error (MSE) and mean absolute error (MAE). The model was optimized using hyper parameter tuning and cross-validation techniques. As a result, it was determined that the best R2 value of 95.65% from the multiple regression models created to estimate the surface roughness could be obtained from the linear regression model. While selecting the optimum process parameters for AWJC, it was determined that nozzle rotation speed, abrasive grain size and flow rate had the greatest effect by 35.5%, 25.4% and 21.9%, respectively. The optimized ANN model showed high accuracy in predicting R a for different input parameter combinations. This study provides a reliable and efficient tool for predicting R a in AWJC, which can contribute to improving process planning and control.