Thermo-swelling properties of particle size cuts of coal maceral concentrates

Xie, Wei; Stanger, Rohan; Lucas, John; Mahoney, Merrick; Elliott, Liza; Yu, Jianglong; Wall, Terry

Title: Thermo-swelling properties of particle size cuts of coal maceral concentrates
Creator: Xie, Wei; Stanger, Rohan; Lucas, John; Mahoney, Merrick; Elliott, Liza; Yu, Jianglong; Wall, Terry
Relation: ARC.DP1097016, ARC.DP140104135 http://purl.org/au-research/grants/arc/DP140104185
Relation: Energy & Fuels Vol. 29, Issue 8, p. 4893-4901
Publisher Link: http://dx.doi.org/10.1021/acs.energyfuels.5b01122
Publisher: American Chemical Society
Resource Type: journal article
Date: 2015
Description: A suite of coal maceral concentrates were prepared from a single coal using a water-based method for two discrete particle size fractions. Coal macerals were produced with the vitrinite content varying from 91.2% to 26.1% for the 106–212 μm particle size fraction and 96.0% to 38.2% for the 212–500 μm particle size fraction. Thermo-swelling of coal maceral concentrates were evaluated by the Computer Aided Thermal Analysis (CATA) technique with extended volumetric measurements. This novel CATA technique allows the apparent specific heat, thermal conductivity, and transient volumetric swelling of the coal sample to be measured simultaneously, as a function of temperature. The experimental results indicated that the maximum swelling (∼510 °C) and high-temperature contraction (600–1000 °C), as well as exothermic heat during primary devolatilization and thermal conductivity at maximum swelling all increased with vitrinite content, with the data inferring a linear relationship, and was independent of particle size, when coal maceral concentrates contain more than 63% vitrinite. A hypothesis for intragranular (within particles) and intergranular (between particles) swelling was used to explain the association of swelling with vitrinite content and particle size. Optical microscopic results of the final pyrolytic residues of different coal maceral concentrates support this hypothesis.
Subject: coal particles; Metaplast; coking; maceral separation
Identifier: http://hdl.handle.net/1959.13/1334645
Identifier: uon:27344
Identifier: ISSN:0887-0624
Language: eng
Reviewed

Hits: 1825
Visitors: 2059
Downloads: 1

		Thumbnail	File	Description	Size	Format