An application of composite soft material microstructure in development and formability of multi-axis dynamic transfer technology

Abstract

This study examines the application of composite soft material microstructure in the technical development of multi-axis dynamic transfer, conducting forecast research aimed at the complementary microstructure. This study uses the PDMS soft materials of different proportions for multi-layer composition to research the characteristics of many composite inner-layer disperse materials and to discuss the mechanical properties of the composite soft materials. One innovation from this research is a multi-axis dynamic mold clamping system, which allows for a discussion of the anisotropic asymmetric dynamic regulation microstructure within the elastic range; controls its appearance characteristics effectively within the elastic range of the microstructure soft mold materials; deduces the appearance characteristics after multi-axis dynamic regulation transfer through the mathematical and geometrical principles; and makes a comparison with the result after the actual impression. The result shows that the composite soft mold proposed in this experiment has a better material mechanical property versus the traditional soft mold, and that the dual-axis dynamic clamping system developed and designed in this research can effectively regulate the microstructure dynamically. Finally, the deduced forecast method also conforms to the experiment result and provides more microstructure-oriented usage and innovation procedures for application in the microstructure industry.