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Research Article

Experimental study on fixed-bed combustion and agglomeration of sawdust–polyethylene mixtures

ORCID Icon, ORCID Icon, ORCID Icon & ORCID Icon
Received 06 Aug 2021, Accepted 10 Jan 2022, Published online: 23 Jan 2022
 

ABSTRACT

Fixed-bed conversion of polymer-containing waste is one of the most common ways of their disposal. One of the problems with such conversion is the cross-sectional non-uniformity of the bed, the formation of agglomerates, and burnouts. The agglomeration process essentially depends on the weight fraction of melting components (plastic materials). Usually, the non-uniformity of the bed is associated with the random nature of the packing (fluctuations of local concentrations and percolation properties). In the present work, we investigate the agglomeration process caused by non-uniform conditions of heat transfer. To this end, combustion of model waste (mixtures of sawdust and polyethylene with a content of the latter of 20–80) is experimentally studied in a laboratory setup with a bed height of about 10 cm. Due to the heat supply through the wall, airflow, non-uniformities developed, associated with different gas permeability in different areas of the bed. The transition from intense thermal decomposition to smoldering is achieved in 5–15 min (the higher the polyethylene content, the shorter the transition time). When the polyethylene content is high, the permeable area decreases so that the air velocity becomes high enough to entrain sawdust particles. As the polymer decomposes, tarry substances are released and form dense deposits in the gas cooling and cleaning system.

Highlights

The dynamics of fixed-bed agglomeration was studied.

New agglomeration mechanism was proposed.

Acknowledgments

The research was carried out under the State Assignment Project (no. FWEU-2021-0005) of the Fundamental Research Program of Russian Federation 2021–2030 and partly supported by the Russian Foundation for Basic Research, Grant No. 19-08-00744 using the resources of the High-Temperature Circuit Multi-Access Research Center (Ministry of Science and Higher Education of the Russian Federation, project no 13.CKP.21.0038).

Disclosure statement

No potential conflict of interest was reported by the author(s).

Additional information

Funding

The research was carried out under the State Assignment Project (no. FWEU-2021-0005) of the Fundamental Research Program of Russian Federation 2021–2030 and partly supported by the Russian Foundation for Basic Research, Grant No. 19-08-00744.

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