Recycling of polyurethane scraps via acidolysis
authors Gama, N; Godinho, B; Marques, G; Silva, R; Barros-Timmons, A; Ferreira, A
nationality International
journal CHEMICAL ENGINEERING JOURNAL
author keywords Recycled polyurethane; Polyurethane foams; Acidolysis; Dicarboxylic acid; Circular economy
keywords WASTE; FOAMS; GLYCOLYSIS; INSIGHTS
abstract Polyurethanes foams (PUF) are used in a wide variety of applications, therefore the quantity of the PUF residues generated is an ecological and environmental problem. Hence, the concerns about the disposal of PUF scraps can be minimized by their recycling. Although some companies are already using acidolysis as a chemical route, the main degradation mechanisms and chemical reactions involved in this recycling process have received little or no attention. Hence, this study aims at contributing to a better understanding of the reaction path(s) involved in the depolymerization of PU. For that purpose, PU wastes of flexible foams were depolymerized using succinic acid and the reaction was monitored using Fourier-transform infrared spectroscopy (FTIR), nuclear magnetic resonance (NMR) and determination of the hydroxyl number (OHnumber) acid value (AV) and amount of water formed during the reaction. The combination of the information obtained suggests that both thermal degradation and reactions between the succinic acid and the PU take place. Additionally, the reaction time interval where further detailed studies need to be carried out in order to optimize this technology was identified. The ensuing recycled polyols (RP) was used as partial substitute of conventional polyol (up to 20% w/w) in the production of rigid foams which were extensively characterized. The foams obtained presented similar morphology and density compared to those derived from conventional polyol and that the presence of the RP increased the flexibility of the foams produced. Therefore, the suitability of this recycling method of PUF and its subsequent use in the production of new foams was demonstrated, which can enhance the Eco efficiency of these materials.
publisher ELSEVIER SCIENCE SA
issn 1385-8947
year published 2020
volume 395
digital object identifier (doi) 10.1016/j.cej.2020.125102
web of science category Engineering, Environmental; Engineering, Chemical
subject category Engineering
unique article identifier WOS:000537395000010
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journal analysis (jcr 2019):
journal impact factor 10.652
5 year journal impact factor 9.43
category normalized journal impact factor percentile 97.361
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