Controlling NOx emission from boilers using waste polyethylene as reburning fuel

I. Oluwoye; Z. Zeng; S. Mosallanejad; M. Altarawneh; J. Gore; B.Z. Dlugogorski

doi:10.1016/j.cej.2021.128427

Back

Controlling NOx emission from boilers using waste polyethylene as reburning fuel

Journal article

Open access

Peer reviewed

Controlling NOx emission from boilers using waste polyethylene as reburning fuel

I. Oluwoye, Z. Zeng, S. Mosallanejad, M. Altarawneh, J. Gore and B.Z. Dlugogorski

Chemical Engineering Journal, Vol.411, Art. 128427

2021

DOI: https://doi.org/10.1016/j.cej.2021.128427

Files and links (2)

pdf

controllingNox.pdfDownload View

Published (Version of Record) Open Access

url

Free to Read *No subscription requiredView

Abstract

Literature lacks data on the performance of waste plastics in controlling NOx emissions in practical combustors operating typically in the temperature window of 1000–1200 °C, under a range of fuel-oxygen equivalence ratios, preventing recycling of plastics in this application. In this contribution, we demonstrate that waste plastics, in particular polyethylene, can serve as a reburning fuel for converting nitrogen oxides (NOx) into environmentally-benign combustion products, in practical large-scale combustors such as pulverised coal power plant, circulation fluidised bed combustion plant, entrained flow boilers, and incinerators. The experiments involved a high-temperature vertically-entrained reactor operating in the range of 600–1200 °C, in conjunction with online infrared spectroscopy, chemiluminescence and gas chromatography. Chemical kinetic modelling, supported by DFT calculations with DMol3 package revealed the underlying chemistry of the NOx mitigation reactions, especially the importance of C2H5 and C2H3 radicals. We modelled the process kinetically and performed a techno-economic assessment of the new technology, to prove its financial feasibility. The reaction of pyrolytic fragments with NOx yields excellent removal efficiency of nitrogen oxides of up to 82% and selectivity to N2 up to 85%, within the temperature range of 1000 °C–1200 °C, and fuel-oxygen equivalent ratios of Φ = 0.8–1.2. While we observed the formation of HCN, the overall nitrogen selectivity shifts towards the formation of N2. Both the conversion of NOx and the selectivity to N2 can be improved further by increasing the residence time. The economic assessment indicates that, the use of waste plastics is comparable to other mainstream solid fuels and becomes less expensive when considering renewable benefits.

Details

Title: Controlling NOx emission from boilers using waste polyethylene as reburning fuel
Authors/Creators: I. Oluwoye (Author/Creator)
Z. Zeng (Author/Creator)
S. Mosallanejad (Author/Creator)
M. Altarawneh (Author/Creator)
J. Gore (Author/Creator)
B.Z. Dlugogorski (Author/Creator)
Publication Details: Chemical Engineering Journal, Vol.411, Art. 128427
Publisher: Elsevier
Identifiers: 991005543742807891
Copyright: © 2021 The Author(s).
Murdoch Affiliation: Chemistry and Physics
Language: English
Resource Type: Journal article

UN Sustainable Development Goals (SDGs)

This output has contributed to the advancement of the following goals:

Source: InCites

Metrics

111 File views/ downloads

79 Record Views

21 Times Cited - Web of Science

InCites Highlights

These are selected metrics from InCites Benchmarking & Analytics tool, related to this output

Collaboration types: Domestic collaboration; International collaboration
Citation topics: 7 Engineering & Materials Science; 7.139 Energy & Fuels; 7.139.89 Gasification
Web Of Science research areas: Engineering, Chemical; Engineering, Environmental
ESI research areas: Engineering