Nov 7, 2014 -- With the growing demand for lightweight designs and composite material applications, part designers and engineers across different industries had been challenged to search for a more innovative yet economic molding solution to stay competitive   while also opening up new opportunities in their  industries. Therefore, the conventional solid injection molding process could no longer satisfy the pressing need to reduce overall production cost while maintaining the competitive advantages for most businesses. Thus, MuCell^®process, a novel approach to composite injection molding, was introduced.

In MuCell^® process, Supercritical Fluid (SCF), usually as nitrogen (N₂ ) or carbon dioxide (CO₂), is mixed with polymer melt to create a uniform single-phase solution, and then injected into the mold cavity. The melt flow with bubbles will foam and form a part. The MuCell^® Process generally offers a 50-75% improvement in key quality measures, such as flatness, roundness, and warpage, while also eliminating all sink marks. These improvements result from the fact that relatively uniform stress patterns are created in the molded part rather than non-uniform stress characteristics of solid molding. When compared with solid injection molding, MuCell^®products rarely have shrinkage problems; the parts that are produced tend to comply far more closely with the mold shape and, presumably, the dimensional specifications of the part itself. In other words, using MuCell^® process can help realize the lightweight design concepts with ease without too much compromise on the product mechanical strength.

However, users of MuCell ^® process often face a difficult task of trying to find a perfect balance between achieving lightweight products and having sufficient mechanical strength of a finished part. As a result, a substantial amount of mold trials using trial-and-error were needed to attain the most optimized processing set-ups and quality finished parts. In order to alleviate the burden of tedious mold trials and provide further simulation insights into the complex MuCell^® process for its users, Moldex3D introduces a new module, Micromechanics Interface to connect with nonlinear multi-scale material modeling software to make the simulation workflow more effective and efficient. Combining with structural analysis, nonlinear multi-scale material modeling software, such as Digimat and Converse, provides the capabilities to simulate the composite materials at micro-macro levels and gives users an opportunity to solve complex nonlinear multi-scale finite element problems. With Moldex3D Micromechanics Interface, users can now output the micromechanics properties of the MuCell^® process, such as cell size and cell density, to Digimat and Converse, which previously was not available, for further structural performance assessment of MuCell^® parts. Hence, the accuracy of the structural analysis of MuCell ^® parts can be further ensured since the microcellular output is considered and incorporated in the structural computation.