REVOLUTIONIZING PRECISION GRINDING: IN-POSITION ELECTRIC SPARK DRESSING FOR METAL BOND DIAMOND WHEELS

Abstract

Metal-bonded diamond grinding wheels, renowned for their robust grinding capabilities and diverse applications, are integral to precision and ultra-precision grinding processes for hard and brittle materials. Exhibiting traits such as formidable grinding prowess, diminished grinding force, reduced grinding temperatures, heightened grinding efficiency, minimal grinding losses, robust abrasive grain adhesion, and economical processing costs, these wheels have garnered significant attention in various industrial sectors. Despite their widespread adoption, challenges persist, notably concerning their inherent shortcomings such as limited self-sharpening and susceptibility to clogging. In this paper, we delve into the intricate dynamics of metal-bonded diamond grinding wheels, aiming to elucidate their performance characteristics, advantages, and limitations. Drawing upon existing research and empirical insights, we explore the nuanced interplay between the structural composition of these wheels and their operational efficacy. Additionally, we scrutinize the underlying mechanisms governing self-sharpening deficiencies and clogging tendencies, thereby providing a comprehensive understanding of the factors influencing wheel performance. Through a synthesis of theoretical frameworks and practical considerations, we propose strategies to mitigate the shortcomings associated with metal-bonded diamond grinding wheels. Our recommendations encompass innovative design modifications, tailored operational parameters, and advanced materials engineering approaches aimed at enhancing wheel self-sharpening and mitigating clogging issues. Furthermore, we underscore the importance of interdisciplinary collaboration and knowledge exchange in fostering continuous advancements within the realm of abrasive machining technologies. By offering insights into the optimization of metal-bonded diamond grinding wheel performance, this paper contributes to the broader discourse on precision machining methodologies. We advocate for a holistic approach that integrates theoretical insights with practical considerations, thereby fostering innovation and efficiency in abrasive machining processes. Ultimately, our findings seek to inform future research endeavors and industry practices, paving the way for enhanced productivity, quality, and sustainability in precision grinding operations