Furthermore, by using a "core back expansion molding process*2" - which enables thicker parts to be manufactured using less plastic raw material - Mazda has successfully developed plastic with a multi-layer structure. The bubbles in the outer layer of the plastic are kept microscopic to ensure each part has the necessary strength and rigidity, while the size of the bubbles in the core layer can be freely adjusted to reduce its density as desired.
With this proprietary technology, substantially less material is needed to manufacture plastic parts that are lighter and have equal or greater strength and rigidity characteristics compared to conventional, non-foamed parts.
This plastic foam molding technology can potentially be applied to nearly all plastic parts used in vehicles. Because the core back molding process enables control of the foam's structure, it is possible to add extra value by enhancing the heat insulation and acoustic characteristics of plastic parts.
Conventional plastic foaming methods use a gas formed through the thermal decomposition of organic and inorganic compounds. However, through the use of SCFs, Mazda's foamed resin molding technology does not result in adverse effects from residual chemical compounds, has a smaller impact on the environment, and produces parts that can be easily recycled.
*1 A supercritical fluid is any substance at a temperature and pressure above its thermodynamic critical point. It can diffuse through solids like a gas, and dissolve materials like a liquid.
Compared to their natural gaseous forms, nitrogen and carbon dioxide, as supercritical fluids, increase the solubility of plastic resin and enable it to form foam with a standardized micro-cell structure.
*2 'Core back' expansion molding is a form of injection molding. Once the foamed resin has filled up the mold, the volume of the mold is increased, causing the foam to expand. This means larger plastic parts, with low density and good rigidity, can be made from the same volume of plastic resin.