Technologies
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WARF: P140042US01

Superior Plastic Parts


INVENTORS -

Lih-Sheng Turng, Xiaofei Sun

The Wisconsin Alumni Research Foundation (WARF) is seeking commercial partners interested in developing a method for fabricating foamed, injection-molded components with improved toughness and ductility.
OVERVIEWPlastics are the most widely used materials in the United States, surpassing steel, copper and aluminum combined by volume. While ubiquitous, fossil-based plastics are becoming more and more costly to produce.

Special injection molding processes can reduce raw material and energy usage, thereby cutting production costs and waste. UW–Madison researchers previously developed one such process called supercritical injection molding foaming technology (SIFT), which uses gas-laden polymer pellets. These pellets are processed by conventional injection molding machines and turned into foamed components.

The process saves on material costs and improves production efficiency. Since less material is used, components formed in this way normally exhibit somewhat reduced ductility and toughness compared to conventional solid injection molded parts. Modifiers like rubber particles and fibers can be used, but are expensive, add weight and degrade the component’s high temperature performance.
THE INVENTIONUW–Madison researchers have developed a new method to create foamed, injection-molded plastic blends with significantly increased toughness and ductility compared to conventional foamed parts.

The new process begins with a polymer blend with two properly selected polymer materials, such as polypropylene (PP) and high-density polyethylene (HDPE), or PP and low-density polyethylene (LDPE), which exhibit a dispersed secondary phase at sub-microscale in the primary matrix. The polymer blend is heated along with a supercritical fluid in an extruder to produce a melt, which is then extruded into gas-laden pellets. The gas-laden pellets can be fed into the injection barrel of a typical machine, plasticized and then injected into a mold cavity (or cavities) where the final part is made.

The process forms a lightweight component with microscale air cavities. Upon tensile loading, debonding of the secondary phase facilitates the interconnection of microcellular voids to form channels such that the stretched component becomes a bundle of fibrils. Compared to other toughening methods, this method achieves a more significant improvement in ductility and toughness. It also has the benefit of higher production efficiency, better dimensional stability, and greater design freedom thanks to the foamed injection molding process.
APPLICATIONS
  • Producing lightweight, high-quality plastic parts with high ductility and toughness for auto, aerospace and sports equipment
KEY BENEFITS
  • Components show significantly improved ductility and toughness
  • High production efficiency
  • Reduced material consumption
  • Better dimensional stability and greater design freedom
  • Method is compatible with standard injection molding machinery.
Contact Information
For current licensing status, please contact Emily Bauer at emily@warf.org or 608-960-9842.
The WARF Advantage

Since its founding in 1925 as the patenting and licensing organization for the University of Wisconsin-Madison, WARF has been working with business and industry to transform university research into products that benefit society. WARF intellectual property managers and licensing staff members are leaders in the field of university-based technology transfer. They are familiar with the intricacies of patenting, have worked with researchers in relevant disciplines, understand industries and markets, and have negotiated innovative licensing strategies to meet the individual needs of business clients.