3D multiphysics model for the simulation of electrochemical machining of stainless steel (SS316)

Gomez-Gallegos, Ares; Mill, Frank; Mount, Andrew R.; Duffield, Steven; Sherlock, Andrew

doi:10.1007/s00170-017-1344-4

Cited by 26 publications

(9 citation statements)

References 36 publications

(53 reference statements)

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“…This shows that the mask electrochemical machining efficiency is higher, the effective current density range (current density >10 A/cm 2 ) is more concentrated, and the entrance accuracy is better. According to Faraday's law, the greater the number of power lines per unit area, the greater the current density [36,37]. Since the voltage between the electrode and the workpiece is constant, the mask can effectively increase the number of power lines per unit area and the current density between the electrode and the workpiece, so the current density of electrochemical machining with mask is higher than that without mask.…”

Section: Simulation Analysis Of Electric Field Distributionmentioning

confidence: 99%

Simulation Analysis and Process Evaluation of Cooling Hole Forming Precision in Mask Assisted Electrochemical Machining Based on GH4169

Dai

2022

Materials

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Good heat dissipation performance of aero-engine an effectively improve the service performance and service life of aero-engine. Therefore, this paper studies the machining method of cooling holes of high-temperature existent material GH 4169 for aero-engine innovatively puts forward the mask electrochemical machining method of cooling holes and explores the entrance morphology and taper formation law of the hole structure of high-temperature resistant material GH 4169. The mathematical model of anode dissolution of cooling holes in ECM is established, and the influence of voltage and electrolyte flow rate on cooling holes in ECM is analyzed. Compared with the mask-less electrochemical machining, the inlet radius of cooling holes in mask electrochemical machining is reduced by about 16.0% and the taper is reduced by 52.8% under the same machining parameters, which indicates that the electrochemical machining efficiency of mask is higher and the machining accuracy is better. Experiments show that the diameter of the mask structure improves the accuracy of the inlet profile of the cooling hole in the ECM. The diameter of the mask increases from 2 mm to 2.8 mm, and the inlet radius of the cooling hole increased from 1.257 mm to 1.451 mm When the diameter of the mask is 2.2 mm, the taper of the cooling hole decreased by 53.4%. The improvement effect is best, and the thickness of the mask has little influence on the forming accuracy of the cooling hole.

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Section: Simulation Analysis Of Electric Field Distributionmentioning

confidence: 99%

Simulation Analysis and Process Evaluation of Cooling Hole Forming Precision in Mask Assisted Electrochemical Machining Based on GH4169

Dai

2022

Materials

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“…Tang [4] improved the flow field divergence problem by optimizing the cathode structure to improve the machining accuracy and stability. Gomez-Gallegos A [5] analyzed the relationship between current density, fluid velocity, conductivity, temperature and overpotential based on the study of an integrated model of cathode, anode and electrolyte. Di [6] proposed to improve the electrolyte flow during Electrochemical machining using a tool cathode leveling method.…”

Section: Introductionmentioning

confidence: 99%

Study on Electrochemical Machining of Involute Internal Spline of Cr-Co-Mo-Ni High Hardness Gear Steel

Huang

Yao²,

Wang³

et al. 2023

Preprint

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Cr-Co-Mo-Ni high-hardness steel is widely used in critical mechanical transmission components. It has the difficult-to-cut characteristic because of its high hardness and high strength. In the cutting process, the machining cutting force is large, the tool is worn quickly, and the machining accuracy is poorly maintained. In view of the machining problems, this paper carried out a research on the electrochemical machining process of internal spline of high hardness gear steel. Firstly, a two-dimensional geometric model of electrochemical machining electric field simulation is established based on the structural characteristics of the internal spline electrochemical machining fixture. The electric field simulation analysis of internal spline electrochemical machining is carried out based on numerical analysis method. The influence law of electrolyte conductivity, processing voltage and cathode feed speed on electrochemical machining forming is studied. Meanwhile, a three-dimensional model of Electrochemical machining flow field simulation is established, and the flow field simulation analysis of internal spline Electrochemical machining is carried out. The influence law of electrolyte flow direction and electrolyte back pressure on the flow field distribution is explored. The platform of electrochemical machining system is set up. An experimental study on electrochemical machining of involute internal splines is carried out to further optimize the electrochemical machining process parameters. The test results showed that the electrolysis accuracy and efficiency of the 41-tooth involute spline workpiece are optimized when the electrolyte is 8% NaNO3, the back pressure of the electrolyte is 0.2 MPa, the feed speed is 1.8 mm/min, and the processing voltage is 16.0 V. The efficiency and accuracy of this proposed method can meet the actual processing needs. It has important application value for advanced machining technology of high-performance materials.

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“…However, they treated the electrolyte as a single-phase flow and neglected the effect of electrolyte bubble rate distribution on machining accuracy. In Gomez-Gallegos et al [15], a 3D coupled multiphysics field finite element model was developed to predict ECM accuracy. In Li et al [16], a coupled model of the magnetic field, electric field, and electrolyte flow in ECM was developed to predict the accuracy of ECM.…”

Section: Introductionmentioning

confidence: 99%

Simulation Analysis of Multi-Physical Field Coupling and Parameter Optimization of ECM Miniature Bearing Outer Ring Based on the Gas-Liquid Two-Phase Turbulent Flow Model

Cao

2022

Micromachines

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Electrochemical machining (ECM) is an essential method for machining miniature bearing outer rings on the high-temperature-resistant nickel-based alloy GH4169. However, the influence of electrolyte temperature distribution and bubble rate distribution on electrolyte conductivity in the ECM area could not be fully considered, resulting in the simulation model not being able to accurately predict the machining accuracy of the outer ring of the miniature bearing, making it challenging to model and predict the optimal process parameters. In this paper, a multiphysics field coupled simulation model of electric, flow, and temperature fields during the ECM of the miniature bearing outer ring is established based on the gas–liquid two-phase turbulent flow model. The simulation analyzed the distribution of electrolyte temperature, bubble rate, flow rate, and current density in the machining area, and the profile change of the outer ring of the miniature bearing during the machining process. The analysis of variance and significance of machining voltage, electrolyte concentration, electrolyte inlet flow rate, and interaction on the mean error of the ECM miniature bearing outer rings was derived from the central composite design. The regression equation between the average error and the process parameters was established, and the optimal combination of process parameters for the average error was predicted, i.e., the minimum value of 0.014 mm could be achieved under the conditions of a machining voltage of 16.20 V, an electrolyte concentration of 9.29%, and an electrolyte inlet flow rate of 11.84 m/s. This is important to improve the machining accuracy of the outer ring of the ECM miniature bearing.

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3D multiphysics model for the simulation of electrochemical machining of stainless steel (SS316)

Cited by 26 publications

References 36 publications

Simulation Analysis and Process Evaluation of Cooling Hole Forming Precision in Mask Assisted Electrochemical Machining Based on GH4169

Simulation Analysis and Process Evaluation of Cooling Hole Forming Precision in Mask Assisted Electrochemical Machining Based on GH4169

Study on Electrochemical Machining of Involute Internal Spline of Cr-Co-Mo-Ni High Hardness Gear Steel

Simulation Analysis of Multi-Physical Field Coupling and Parameter Optimization of ECM Miniature Bearing Outer Ring Based on the Gas-Liquid Two-Phase Turbulent Flow Model

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