Abstract
Electrochemical trepanning (ECTr) is an effective method for machining the ruled surface parts. Generally, the forward flow mode is used in ECTr, under which the streamlines at the outlet are divergent, resulting in the obvious flow patterns at the outlet and the instability of the machining process. In ECTr of a diffuser with a special structure, the lateral flow mode is adopted to improve the uniformity of the flow field, thereby improving the surface quality at the hub. ECTr is a complicated multiphysics coupling process. To investigate the distributions of electric field, two-phase flow field and thermal field in ECTr with lateral flow, a multiphysics coupling field model was established. In this model, a coupling relationship was formed between the various physical fields through the change of the electrolyte conductivity. And a coupled multiphysics simulation was performed to show how the gas bubbles volume fraction, electrolyte temperature, electrolyte conductivity and current density change along the flow path. Compared with the inlet of the electrolyte, the gas bubbles volume fraction and the temperature at the outlet increased by 38.8% and 6.3 K, respectively. Under the combined influence, the conductivity decreased by 7.227 S/m at the outlet, resulting in a decrease of 57.81 A/cm2 in the current density. The simulation results were then verified against those from a corresponding experiment involving lateral flow ECTr. Along the flow path, the thickness of the machined blade gradually increased, varying from 2.09 mm to 2.76 mm. The surface quality gradually deteriorated along the flow path and the surface roughness varied from Ra 0.72 μm to Ra 1.05 μm. Combining the simulation and the experiment, the correctness and the effectiveness of the multiphysics coupling model and simulation were confirmed. The results can be applied to other ECM processes.
Highlights
Electrochemical machining (ECM) is based on electrochemical anodic dissolution, which is a multiphysics coupling process [1]
Through establishing electric flied model, Skinn el al compared primary current distribution simulations with indentations fabricated by ECM of steel panels [5].The distribution of the current density under a flexible auxiliary electrode mechanism was obtained in counter-rotating ECM [6]
This paper focuses on the distributions of physical fields in Electrochemical trepanning (ECTr) of lateral flow under the analysis of multiphysics coupling
Summary
Electrochemical machining (ECM) is based on electrochemical anodic dissolution, which is a multiphysics coupling process [1]. By establishing the thermal field model in ECM, Clark and Mcgeough analyzed the distribution of temperature along the machining gap [7]. Because of the characteristics of the multi-physical coupling process for ECM, it is essential to develop the analysis of multiphysics coupling field for further enhancing the machining quality. Mi el al established the model of electric field and two-phase flow field coupling without considering the change of the electrolyte temperature [10]. For investigating the distribution of each physical field in ECTr, a model was established, which involved electric field, two-phase flow field and thermal field. Through the multiphysics coupling simulation, the changes of the gas bubbles volume fraction, the electrolyte temperature, the electrolyte conductivity and the current density in machining gap were examined along the flow path. Through analyzing the machining accuracy and the surface quality of the machined blade, the simulation results were verified effectively
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