Abstract
In electrochemical machining (ECM), it is important to design the shape of an appropriate tool capable of producing a workpiece of desired shape. This work presents a numerical approach to solving the two- and three-dimensional tool design problem in steady-state ECM. The tool design problem is transformed into a shape optimization problem and then solved using the continuous adjoint method combined with elements of shape calculus, ensuring high efficiency and the maximum possible degrees of freedom. A numerical experiment on a two-dimensional Gaussian-shaped workpiece shows a good agreement of the calculated tool shape with the exact analytical solution. Tool design is carried out for a series of two- and three-dimensional workpiece shapes to investigate the influence of the curvature of the desired workpiece on the front gap width in steady-state ECM.
Original language | English |
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Pages (from-to) | 198-210 |
Number of pages | 13 |
Journal | Chemical Engineering Science |
Volume | 106 |
DOIs | |
State | Published - 17 Mar 2014 |
Keywords
- Design
- Electrochemistry
- Materials processing
- Numerical analysis
- Optimization