Abstract
Machining of Titanium alloys (Ti6Al4V) becomes more vital due to its essential role in biomedical, aerospace, and many other industries owing to the enhanced engineering properties. In the current study, a Box–Behnken design of the response surface methodology (RSM) was used to investigate the performance of the abrasive water jet machining (AWJM) of Ti6Al4V. For process parameter optimization, a systematic strategy combining RSM and a heat-transfer search (HTS) algorithm was investigated. The nozzle traverse speed (Tv), abrasive mass flow rate (Af), and stand-off distance (Sd) were selected as AWJM variables, whereas the material removal rate (MRR), surface roughness (SR), and kerf taper angle (θ) were considered as output responses. Statistical models were developed for the response, and Analysis of variance (ANOVA) was executed for determining the robustness of responses. The single objective optimization result yielded a maximum MRR of 0.2304 g/min (at Tv of 250 mm/min, Af of 500 g/min, and Sd of 1.5 mm), a minimum SR of 2.99 µm, and a minimum θ of 1.72 (both responses at Tv of 150 mm/min, Af of 500 g/min, and Sd of 1.5 mm). A multi-objective HTS algorithm was implemented, and Pareto optimal points were produced. 3D and 2D plots were plotted using Pareto optimal points, which highlighted the non-dominant feasible solutions. The effectiveness of the suggested model was proved in predicting and optimizing the AWJM variables. The surface morphology of the machined surfaces was investigated using the scanning electron microscope. The confirmation test was performed using optimized cutting parameters to validate the results.
Highlights
Owing to excellent advantageous properties such as a low elastic modulus, high corrosion resistance, excellent strength, weldability, and heat-treatable nature, the titanium Ti6Al4V alloys have become more popular in widespread application areas such as automobiles, jet engines, power-generating components, body frame of aircraft, and medicated implants [1,2]
The present study investigated the effect of abrasive water jet machining (AWJM) parameters (Tv, abrasive mass flow rate (Af), and standoff distance (Sd)) on responses of material removal rate (MRR), surface roughness (SR), and the Kerf taper angle for Ti6Al4V
Mathematical regression models were generated using the response surface methodology (RSM) technique, and Analysis of variance (ANOVA) results have shown the adequacy of the developed models
Summary
Owing to excellent advantageous properties such as a low elastic modulus, high corrosion resistance, excellent strength, weldability, and heat-treatable nature, the titanium Ti6Al4V alloys have become more popular in widespread application areas such as automobiles, jet engines, power-generating components, body frame of aircraft, and medicated implants [1,2]. Chaturvedi et al [6] investigated the optimization of AWJM variables for machining of Ti6Al4V alloy They performed experiments using an L25 orthogonal array considering the pressure, stopping distance, transverse speed, and abrasive throughput as process variables and surface roughness, MRR, machining time, HRC strength of the machined part as a response. Materials 2021, 14, 7746 objective optimization using WASPAS and MOORA techniques for input controllable parameters of AWJM such as Tv, Af, and Sd, which influences performance characteristics of MRR, kerf width, and SR. They performed experiments on the Inconel-625 workpiece.
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