PU-Materials can be Depolymerized into Monomeric Building Blocks Through Chemical Recycling
Polyurethane (PU) is one of the most versatile thermoset synthetic polymers which through careful choice of monomer and formulation, can be seen in a myriad of different forms ranging from rigid-, flexible and molded foams to adhesives and elastomers just to name a few.
Through its many forms, PU is seen in a plethora of different product like shoes, mattresses, and insolation material but also in more sophisticated products like wind turbine blades and components within aircrafts and cars. With a global production estimated to be above 22 million tons, increasing demand and production results in an ever-increasing amount of PU-waste, but here, the lack of good recycling methods means that most PU is send for energy recovery through incineration or is landfilled.Related Stories
- RF Proximity Sensors - Characteristics, Operation and Application in Materials Recycling
- Selecting a Lubricant for a Compressor in the Chemical Industry
- Mineral Building Materials: Properties and Solutions for Analysis
New research by the RePURpose consortium in ChemSusChem spearheaded by Prof Troels Skrydstrup and Ass. Prof. Steffan Kvist Kristensen has now shown that commercial and end-of-life PU-materials can be depolymerized into monomeric building blocks through chemical recycling. Where current PU‑recycling methods generate a secondary PU-material with other characteristics than the original material, this newly developed methodology has the potential to create virgin polymeric material with the same characteristics as the original material.
In the present study, researchers from the Interdisciplinary Nanoscience Center, iNANO, and Department of Chemistry at Aarhus University, reports that a catalytic system based on the earth-abundant base metal manganese, dihydrogen and isopropyl alcohol is effective for deconstructing different PU-materials into a polyol and an amine fraction representing the original monomeric compositions. The authors go to show, that the system can be used on gram scale even at low catalyst loading without diminishing the activity.
In an effort to reduce our plastic footprint and dependency on fossil fuels a change from the current linear model (make-use-dispose) towards a circular plastic economy, where PU is produced, used, recovered and recycled into new PU-materials is needed. The usage of an earth-abundant metal, a green solvent and the potential adaption towards green hydrogen could pave the way towards a circular plastic economy for PU.
» Publication Date: 04/10/2021