Issue 12, 2024

ChemPren: a new and economical technology for conversion of waste plastics to light olefins

Abstract

With the ever-increasing demand for plastics, sustainable recycling methods are key necessities. The current plastics industry can manage to recycle only 10% of the 400 million metric tons of plastic produced globally. Waste plastics, in the current infrastructure, land up mostly in landfills. Although a lot of research efforts have been spent on processing and recycling co-mingled mixed plastics, energy-efficient sustainable and scalable routes for plastic upcycling are still lacking. Catalytic valorization of waste plastic feedstock is one of the potential scalable routes for plastic upcycling. Silica-alumina based materials, and zeolites have shown a lot of promise. A major interest lies in restricting catalyst deactivation, and refining product selectivity and yield for such catalytic processes. This article highlights ChemPren technology as a clean energy solution to waste plastic recycling. Co-mingled, mixed plastic feedstock along with spray dried, attrition resistant, ZSM-5 containing catalysts is preprocessed with an extruder to form optimally sized particles and fed into a fluidized bed reactor for short contact times to produce selectively and in high yields ethylenes, propylenes and butylenes. This techno-economic perspective indicates that the ChemPren technology can produce propylene at $0.16 per lb, whereas the current selling price of virgin propylene is $0.54 per lb. This technology can serve as a platform for mixed plastic upcycling, with more advancements necessary in the form of robust and resilient catalysts and reactor operation strategies for tuning product selectivity.

Graphical abstract: ChemPren: a new and economical technology for conversion of waste plastics to light olefins

Article information

Article type
Perspective
Submitted
18 Jūl. 2024
Accepted
07 Okt. 2024
First published
07 Okt. 2024

React. Chem. Eng., 2024,9, 3100-3104

ChemPren: a new and economical technology for conversion of waste plastics to light olefins

A. Gaffney, D. Maiti, D. Kuila and G. Mafia, React. Chem. Eng., 2024, 9, 3100 DOI: 10.1039/D4RE00354C

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