Modeling and experimental study on micro-fracture behavior and restraining technology in micro-grinding of glass

Abstract

This study presents a new fracture restraining technique for micro-grinding of glass and micro-fracture behavior in micro-grinding of glass is investigated. Penetration depth p0 and loading force Fg of single abrasive are discussed. A predicting model, which quantitatively predicts fracture size lc, is built based on single abrasive micro-interaction theory and elastic strain energy theory. A novel micro-fracture restraining coat, made with resin material, is developed and fabricated onto the work piece׳s surface to provide an extra restraining force for micro-grinding. Experimental machining examples indicate that lcy is reduced from 232.64μm to 32.61μm, and a promotion of 50 times productivity is achieved. Moreover, acrylic resin and epoxy resin are tested for different resins, and it is found that epoxy resin coat provides a ductile mode propelling effect, and acrylic resin coat induces a non-uniform effect which causes a large fracture size and its rapid growth. It is demonstrated that this technology successfully restrains the fracture formation during micro-grinding of glass, and this study proposes the analytical model that captures the main trend of lc results in this experiment. Application of this knowledge is expected to significantly contribute to the precision micro-machining industry of hard–brittle materials.