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TG-FTIR investigations of the pyrolysis of polyurethanes: Quantitative carbon dioxide tracing, decomposition mechanisms, products and mass balances for advanced recycling

Michael Zeller, Daniela Merz, Luca Weigel, Salar Tavakkol, Dieter Stapf

2025Journal of Analytical and Applied Pyrolysis18 citationsDOIOpen Access PDF

Abstract

Polyurethanes (PUR) are versatile polymers used in a broad range of applications. Conventional mechanical recycling is thus difficult. Chemical recycling such as pyrolytic waste treatment presents new recycling options. Advanced recycling by pyrolysis may help to reduce environmental impacts from PUR wastes. The knowledge of mechanisms, products and yields is essential for the design of efficient pyrolysis processes. Rigid (RPUF) and flexible foams (FPUF), a cast elastomer (CE) and a thermoplastic Polyurethane (TPU) have been investigated by thermogravimetry (TG) and FTIR-spectroscopy. Two decomposition steps have been identified. CO 2 is mainly released in the first decomposition step between 250 °C and 400 °C. The second decomposition step at temperatures above 400 °C releases polyol fragments and marginal amounts of CO 2 . Strong feedstock dependency is evident. Quantitative tracing for the CO 2 release was developed, validated and applied. This allows the resolution of specific decomposition phenomena, mass balancing and distinguishing potentially valuable volatiles from CO 2 and solid residues. CO 2 yields are 12.0 mass-% for RPUF, 4.0 mass-% for FPUF, 3.2 mass-% for CE and 5.3 mass-% for TPU. Considering solids and CO 2 as losses, recycling potentials were determined which are 74 mass-% for RPUF, 90 mass-% for FPUF, 95 mass% for CE and 93 mass-% for TPU. This facilitates further process development based on polymer-specific data. • Quantitative CO 2 tracing for polyurethane pyrolysis in TG-FTIR is presented. • Pyrolysis of polyurethane yields 3–12 mass-% of CO 2 , dependent on the feedstock. • Quantification of non-volatiles and CO 2 enables assessment of recycling potentials. • Recycling potentials are 74–95 mass-%.

Topics & Concepts

PyrolysisDecompositionCarbon dioxideFourier transform infrared spectroscopyChemistryChemical engineeringMass spectrometryTracingOrganic chemistryChromatographyComputer scienceEngineeringOperating systemCarbon dioxide utilization in catalysisPolymer composites and self-healingPolymer crystallization and properties
TG-FTIR investigations of the pyrolysis of polyurethanes: Quantitative carbon dioxide tracing, decomposition mechanisms, products and mass balances for advanced recycling | Litcius