A growing industrial demand for multifunctional bio-friendly raw materials is pushing researchers to develop value-added and energy-saving biocomposites and processes. Now, researchers at University of British Columbia Okanagan are manufacturing environmentally friendly stone composites using polymers and natural stone slurry waste.
These new composites are made of materials previously discarded from construction supplies or cutting of blocks (structural or ornamental) for monuments. While reusing the waste material of natural stone production is common in cement, tile and concrete industry, adding the stone slurry to polymers is a new and innovative idea, explains School of Engineering Professor Abbas Milani.
“Because the slurry is a waste material, it comes at a lower cost for recycled composite production,” says Milani, director of UBC’s Materials and Manufacturing Research Institute (MMRI).
Milani and his colleagues recently received UBC eminence funding to establish a cluster of research excellence in biocomposites. The cluster will develop novel agricultural and forestry-based bio-and recycled composites to minimize the impact of conventional plastics and waste on the environment.
The powdered stone waste used in the project provides flexibility to the new particulate polymer matrix composite. It can be mixed at different ratios into the finished product through appropriate heat or pressure to meet structural requirements or aesthetic choices, defined by industry and customers.
“This green stone composite can easily be integrated into a variety of applications,” says UBC Research Associate Davoud Karimi. “These composites can be used in decorations and sanitation products ranging from aerospace to automotive applications.”
The researchers varied the amount of stone added to the composites then tested several parameters to determine strength, durability and density along with thermal conductivity. The molding and mechanical tests were conducted in the Composites Research Network Okanagan Laboratory with collaboration from the MMRI.
By adding the stone waste to the composites, researchers determined that it not only increased the virgin polymer’s strength and durability, but the composites’ conductivity increased proportionally based on the amount of stone added.
“The increased strength is important, but the increased conductivity (up to 500 per cent) opens a huge door to several new potential applications, including 3D printing with recycled composites,” explains Milani.
“Any time we can divert waste from landfills and generate a product with the potential of economic benefit is a win-win,” Milani adds. “We hope that these sorts of products, that are carefully designed with the aid of multi-disciplinary researchers focused on 3R measures (repairable, reusable, and recyclable), can significantly contribute to the economy of our region and Canada as a whole.”
The research was funded by the Natural Sciences and Engineering Research Council (NSERC) and the National Research Institute for Science Policy (NRISP). It was recently published in the journals Composite Structures and Composites Part B: Engineering.