Thermoplastic development of coking and non-coking maceral concentrates and molecular weight distribution of their pyrolysis products

Tran, Quang Anh; Stanger, Rohan; Xie, Wei; Smith, Nathan; Lucas, John; Wall, Terry

Title: Thermoplastic development of coking and non-coking maceral concentrates and molecular weight distribution of their pyrolysis products
Creator: Tran, Quang Anh; Stanger, Rohan; Xie, Wei; Smith, Nathan; Lucas, John; Wall, Terry
Relation: ARC.DP140104185 http://purl.org/au-research/grants/arc/DP140104185
Relation: Journal of Analytical and Applied Pyrolysis Vol. 129, p. 72-85
Publisher Link: http://dx.doi.org/10.1016/j.jaap.2017.12.001
Publisher: Elsevier
Resource Type: journal article
Date: 2018
Description: A suit of nitrogen-dried maceral concentrates derived from a coking coal and a non-coking coal was investigated to reveal the impact of varying coal main organic constituent, the vitrinite, on their thermoplasticity and pyrolysis products. The thermoplastic development of maceral concentrates during pyrolysis was evaluated via their thermo-swelling and dynamic volatile release. These measurements were then linked to molecular weight distributions of vaporised tars and tetrahydrofuran (THF) extracts obtained from heat-treated samples. Regardless of the vitrinite content, only coking macerals agglomerated during pyrolysis while non-coking macerals retained their powdered structure. This result indicated that although concentrating the vitrinite could alter the extent of coal thermoplasticity, such process could not grant or remove thermoplasticity from a maceral concentrate. This was reflected in the similar molecular weight distribution of solvent extracts produced between the parent coals and their concentrates. In specific, coking concentrates generated extractable materials with a relatively more complex structure, consisting of a bimodal molecular weight distribution with 12–14 Da repeating structures at <600 Da and 24 Da reoccurring units between 600 and ∼1500 Da. Solvent extracts isolated from non-coking concentrates, on the other hand, possessed a unimodal molecular weight distribution with only 12–14 Da repeating structures extending to ∼800 Da. The absence of high-range molecular weight materials (the 24 Da repeating units) in non-coking coal and its concentrates was speculated to play a vital role to their inability to exhibit thermoplastic behaviour during pyrolysis.
Subject: coal macerals; coking coal; solvent extract; metaplast; coal pyrolysis
Identifier: http://hdl.handle.net/1959.13/1442856
Identifier: uon:41817
Identifier: ISSN:0165-2370
Language: eng
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