Simulating electroplated micro surfaces in 3-D

A H. J. Jeon (1), J Low (1), A. R. Mileham (1), A.N. Bramley (1), C. Johal (2)
1 Department of Mechanical Engineering, University of Bath, BA27AY, UK
2 Glacier Vandervell Bearings Ltd, Rugby, UK

Abstract

This paper describes the development, comparison and validation of a 3-D model of the electroplating process. It is based on the current density distribution that is generated using the Finite Element Method (FEM) and is used together with Faraday's law of electrolysis and various material and electrolyte values to determine the local plating depth. It has been developed initially to model the depth of the micro layer deposited on the work surface of an automotive engine’s "big end" shell bearing. Actual plating trials were conducted in a series of controlled laboratory experiments using an industrial type jig and industrial plating conditions. These consisted of a steel cathode (the bearing) and a lead anode. The results described here, in this paper, show good agreement between the 3-D simulation and the actual plating depth and profile and are considered to validate the model sufficiently for it to be used for electroplating tooling design and micro-electroforming.