The application of metal bonded grinding wheels generally results in high wear resistance and profile constancies of the grinding wheels. Especially bronze bonded grinding wheels can efficiently be used for the grinding tasks, as it is easier to modify their chemical composition - and therefore their bond hardness - to suit a specific grinding task. The combination of very small grained diamonds and a metal bond causes great difficulties for conventional dressing. In this paper, an assessment on the capabilities of ELID for dressing of bronze bonded diamond grinding wheels is presented. Distinct types of bronze-bonds with different chemical composition are investigated regarding their electrochemical dissolution and oxidation behaviour during ELID. Iron-based (Fe-Bz) and cobalt-based (Co-Bz) bronze-bond types showed good performance regarding oxide layer formation during the pre-dressing. An extensive oxide layer growth prevents the metal bond from a too fast anodic dissolution. In contrast, pure bronze type (Cu-Bz) showed no closed oxide layer formation resulting in an extensive anodic dissolution of the grinding wheel bond.
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