location: Current position: Home >> Scientific Research >> Paper Publications

Model for the Evolution of Pore Structure in a Lignite Particle during Pyrolysis. 2. Influence of Cross-Linking Reactions, Molten Metaplast, and Molten Ash on Particle Surface Area

Hits:

Indexed by:期刊论文

Date of Publication:2017-08-01

Journal:ENERGY & FUELS

Included Journals:SCIE、EI、Scopus

Volume:31

Issue:8

Page Number:8036-8044

ISSN No.:0887-0624

Abstract:A model for the evolution of the pore structure in a lignite particle during pyrolysis was established previously based on the chemical percolation devolatilization (CPD) model, using coal polymer network parameters to calculate the surface area and porosity of the particle. In this paper, to get the accurate surface area of coal particle at high pyrolysis temperature, the previous model was improved by considering the effects of cross-linking reactions, molten Metaplast, and ash. The good agreement of the predicted surface area with experiments at temperature below 1200 K in the previous model is maintained, and model accuracy is improved at temperatures above 1200 K. A correlation between cross-links and cleaving of side chains was established to describe the increasing amount of cross-links during coal pyrolysis and was introduced to modify the amount of bridges calculated by the CPD model. Higher temperatures can provide more energy for cleaving of side chains, and therefore the cross-linking reactions have a greater influence on the change of the surface area in a lignite particle during pyrolysis at a higher temperature. The influence of Metaplast on the surface area of a lignite particle is limited. The molten ash reduces the particle surface area at high temperature, and this influence is larger on the CO2 surface area than on the N-2 surface area.

Pre One:Hydrogen production by catalytic methane decomposition: Carbon materials as catalysts or catalyst supports

Next One:Online analysis of initial volatile products of Shenhua coal and its macerals with pyrolysis vacuum ultraviolet photoionization mass spectrometry